Your search keyword '"Earthquake ground motions and engineering seismology"' showing total 81 results

1. Reconstructing Late Quaternary Paleovalley Systems of Italy Through mHVSR: A Tool for Seismic Hazard Assessment in Modern Coastal Lowlands.

Author

Di Martino, Andrea, Sgattoni, Giulia, Di Paola, Gianluigi, Berti, Matteo, and Amorosi, Alessandro

Subjects

*SEISMIC wave velocity, *SEISMIC waves, *GROUND motion, *SHEAR waves, *GEOPHYSICAL prospecting, *COASTAL sediments, *HAZARD mitigation, *EARTHQUAKE hazard analysis

Abstract

Effective site characterization in highly urbanized coastal lowlands requires accurate stratigraphic and geophysical investigations. In these regions, which typically host shallowly buried paleovalley systems formed in response to Quaternary glacio‐eustatic fluctuations, the marked lithologic contrast between soft sediment paleovalley fills and the adjacent, stiff substrate has the potential to modify earthquake motions, and assessment of critical parameters, such as shear wave velocities (VS) and resonance frequencies (f), should be coupled with detailed stratigraphic architecture. To evaluate the potential of the microtremor horizontal‐to‐vertical spectral ratio (mHVSR) for paleovalley recognition and mapping, we performed mHVSR measurements along the Adriatic coastal plain of Italy, where two paleovalley systems (Pescara and Manfredonia) have been recently identified. In both areas, we detected rapid lateral variations in resonance frequencies and highlighted laterally continuous impedance contrasts. Relying on a robust stratigraphic framework, we carefully evaluated the relation between geological and geophysical data and identified the stratigraphic surfaces responsible for the observed resonances. We derived VS models for the sediment fill, reconstructing the geometry of the two buried paleovalleys. We address the importance of evaluating the geological context when designing microzonation studies, for a reliable interpretation of changes in resonance frequencies. Plain Language Summary: When earthquakes occur, buildings shake differently based on several factors, including seismic wave velocity, natural resonance frequencies, and local geological characteristics. Beneath modern coastal lowlands, the presence of paleovalley systems can significantly modify the ground motion. Identification of these buried bodies is therefore essential to assess and reduce seismic hazard. Paleovalleys are shallow incisions formed under periods of fluvial erosion in response to Quaternary climate fluctuations, and subsequently filled with very soft clay. These bodies are found worldwide, and do not have any geomorphological evidence, making their recognition challenging. Geologists typically use expensive sediment core analysis to identify paleovalleys, but this method can only provide spotty information. Geophysical exploration techniques that rely on microtremors (small vibrations on the Earth) can complement mapping of these buried bodies. In this work, we tested this technique in Pescara and Mafredonia (Adriatic coastal plain, Italy), providing dense information about paleovalley geometries and geophysical parameters crucial for predicting how the ground will shake during an earthquake. This study also highlights the importance of integrating disciplines to improve our understanding of subsoil and to design future studies to mitigate seismic hazards. Key Points: Paleovalley fills are key sediment bodies made up of soft clay, tens of m thick and few km wide, buried beneath coastal lowlands worldwideMicrotremor‐based paleovalley profiles and stratigraphic cross‐sections exhibit strong similarityMicrotremor can provide shear wave velocities and resonance frequencies of paleovalleys, key parameters for seismic hazard mitigation [ABSTRACT FROM AUTHOR]

Published

2023

2. Climate Impact Comparison of Electric and Gas‐Powered End‐User Appliances

Author

Dietrich, Florian, Chen, Jia, Shekhar, Ankit, Lober, Sebastian, Krämer, Konstantin, Leggett, Graham, Veen, Carina van der, Velzeboer, Ilona, Gon, Hugo Denier van der, Röckmann, Thomas, Sub Algemeen Marine & Atmospheric Res, Sub Atmospheric physics and chemistry, Marine and Atmospheric Research, Sub Algemeen Marine & Atmospheric Res, Sub Atmospheric physics and chemistry, and Marine and Atmospheric Research

Subjects

ecosystem health, ATMOSPHERIC COMPOSITION AND STRUCTURE, Air/sea constituent fluxes, Biosphere/atmosphere interactions, Evolution of the atmosphere, Volcanic effects, BIOGEOSCIENCES, Climate dynamics, Modeling, COMPUTATIONAL GEOPHYSICS, Numerical solutions, CRYOSPHERE, Avalanches, Mass balance, GEODESY AND GRAVITY, Ocean monitoring with geodetic techniques, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Global change from geodesy, GLOBAL CHANGE, Atmosphere, Abrupt/rapid climate change, Climate variability, Earth system modeling, Impacts of global change, Land/atmosphere interactions, Oceans, Regional climate change, Sea level change, Solid Earth, Water cycles, HYDROLOGY, Climate impacts, Hydrological cycles and budgets, INFORMATICS, MARINE GEOLOGY AND GEOPHYSICS, Gravity and isostasy, ATMOSPHERIC PROCESSES, Climate change and variability, Climatology, General circulation, Ocean/atmosphere interactions, Regional modeling, Theoretical modeling, OCEANOGRAPHY: GENERAL, Climate and interannual variability, Numerical modeling, NATURAL HAZARDS, Atmospheric, Geological, Oceanic, Physical modeling, Climate impact, Risk, Disaster risk analysis and assessment, OCEANOGRAPHY: PHYSICAL, Air/sea interactions, Decadal ocean variability, Ocean influence of Earth rotation, Sea level: variations and mean, Surface waves and tides, Tsunamis and storm surges, PALEOCEANOGRAPHY, POLICY SCIENCES, Benefit-cost analysis, RADIO SCIENCE, Radio oceanography, SEISMOLOGY, Earthquake ground motions and engineering seismology, Volcano seismology, TECTONOPHYSICS, Evolution of the Earth, VOLCANOLOGY, Volcano/climate interactions, Atmospheric effects, Volcano monitoring, Effusive volcanism, Mud volcanism, Explosive volcanism, Volcanic hazards and risks, Research Article, climate change, methane, carbon dioxide, emissions, carbon mitigation, global [GEOHEALTH, Impacts of climate change], Environmental Science(all), Earth and Planetary Sciences (miscellaneous), global, ddc, General Environmental Science

Abstract

Natural gas is considered a bridging technology in the energy transition because it produces fewer carbon emissions than coal, for example. However, when leaks exist, methane is released into the atmosphere, leading to a dramatic increase in the carbon footprint of natural gas, as methane is a much stronger greenhouse gas than carbon dioxide. Therefore, we conducted a detailed study of methane emissions from gas-powered end-use appliances and then compared their climate impacts with those of electricity-powered appliances. We used the Munich Oktoberfest as a case study and then extended the study to 25 major natural gas consuming countries. This showed that electricity has been the more climate-friendly energy source at Oktoberfest since 2005, due to the extensive use of renewable electricity at the festival and the presence of methane emissions, particularly caused by the incomplete combustion of natural gas in cooking and heating appliances. By contrast, at the global level, our study shows that natural gas still produces lower end-use carbon emissions than electricity in 18 of the 25 countries studied. However, as the share of renewable energy in the electricity mix steadily increases in most countries, the carbon footprint of electricity will be lower than that of natural gas in these countries in the near future. These findings from our comparison of the total carbon emissions of electric and gas-powered end-use appliances can help inform the debate on how to effectively address climate change., Earth's Future, 11 (2), ISSN:2328-4277

Published

2023

3. Ecological Calendars of the Pamir Mountains: Illustrating the Importance of Context‐Specificity for Food Security

Author

A. L. Ullmann, I. Haag, and U. Bulbulshoev

Subjects

Global and Planetary Change, Epidemiology, Health, Toxicology and Mutagenesis, Public Health, Environmental and Occupational Health, Management, Monitoring, Policy and Law, Pollution, Waste Management and Disposal, ddc, Ecological Calendars and Anticipating the Anthropogenic Climate Crisis, ATMOSPHERIC COMPOSITION AND STRUCTURE, Air/sea constituent fluxes, Volcanic effects, BIOGEOSCIENCES, Climate dynamics, Modeling, COMPUTATIONAL GEOPHYSICS, Numerical solutions, CRYOSPHERE, Avalanches, Mass balance, GEODESY AND GRAVITY, Ocean monitoring with geodetic techniques, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Global change from geodesy, GLOBAL CHANGE, Regional climate change, Abrupt/rapid climate change, Climate variability, Earth system modeling, Impacts of global change, Land/atmosphere interactions, Oceans, Sea level change, Solid Earth, Water cycles, HYDROLOGY, Climate impacts, Hydrological cycles and budgets, INFORMATICS, MARINE GEOLOGY AND GEOPHYSICS, Gravity and isostasy, ATMOSPHERIC PROCESSES, Climate change and variability, Climatology, General circulation, Ocean/atmosphere interactions, Regional modeling, Theoretical modeling, OCEANOGRAPHY: GENERAL, Climate and interannual variability, Numerical modeling, NATURAL HAZARDS, Sustainable development, Community management, Atmospheric, Geological, Oceanic, Physical modeling, Climate impact, Risk, Disaster risk analysis and assessment, OCEANOGRAPHY: PHYSICAL, Air/sea interactions, Decadal ocean variability, Ocean influence of Earth rotation, Sea level: variations and mean, Surface waves and tides, Tsunamis and storm surges, PALEOCEANOGRAPHY, POLICY SCIENCES, Benefit-cost analysis, RADIO SCIENCE, Radio oceanography, SEISMOLOGY, Earthquake ground motions and engineering seismology, Volcano seismology, VOLCANOLOGY, Volcano/climate interactions, Atmospheric effects, Volcano monitoring, Effusive volcanism, Mud volcanism, Explosive volcanism, Volcanic hazards and risks, GEOGRAPHIC LOCATION, Asia, Research Article, transdisciplinary research, Indigenous knowledge, praxis, climate adaptation, human ecology, iconographic communication [Rhythms of the Earth], Water Science and Technology

Abstract

Communities in the Pamir Mountains of Central Asia are among the most vulnerable to climate change due to their geographic location and subsistence-based livelihoods. Historically, ecological calendars supported their agropastoral lifestyles which provided anticipatory capacity to seasonal changes. Due to decades of Soviet colonization and socioecological transformations, knowledge of these ecological calendars fell into disuse. In 2016, Savnob and Roshorv, two villages in the Bartang Valley of Tajikistan, began the revitalization of these calendars using a participatory action research process through knowledge co-generation. We undertook a comparative analysis to investigate the importance of context-specificity to ensure food security and reduce their vulnerability to climate change. A preliminary analysis of the temperature regime and local language terms, relating to the positioning and quality of land, framed our methods-of-analysis. We compared the villagers' ecological calendars by focusing on indicator species, potentially threatening weather events, land-use, livelihood activities, and the role of the vernal equinox. Despite their close geographic proximity, context-specificity determined by distinct microecologies influences the timing and practice of these communities' livelihood activities. These villages have different dependencies on biotic and abiotic events, crops, and land-use; all of which affect food security and survival. These differences contributed to mutual support between the two villages, increased the availability of food, and thereby, lowered their vulnerability to climate change. As Savnob's and Roshorv's ecological calendars are updated with changing climate, they can once again enhance their anticipatory capacity while reducing their vulnerability.

Published

2022

4. Numerical Modeling of Gas Hydrate Recycling in Complex Media: Implications for Gas Migration Through Strongly Anisotropic Layers

Author

A. Peiraviminaei, S. Gupta, and B. Wohlmuth

Subjects

Geophysics, GENERAL, Climate and interannual variability, Numerical modeling, NATURAL HAZARDS, Atmospheric, Geological, Oceanic, Physical modeling, Climate impact, Risk, Disaster risk analysis and assessment, OCEANOGRAPHY: PHYSICAL, Air/sea interactions, Decadal ocean variability, Ocean influence of Earth rotation, Sea level: variations and mean, Surface waves and tides, Tsunamis and storm surges, PALEOCEANOGRAPHY, POLICY SCIENCES, Benefit-cost analysis, RADIO SCIENCE, Radio oceanography, SEISMOLOGY, Earthquake ground motions and engineering seismology, Volcano seismology, VOLCANOLOGY, Volcano/climate interactions, Atmospheric effects, Volcano monitoring, Effusive volcanism, Mud volcanism, Explosive volcanism, Volcanic hazards and risks, Research Article [Geomagnetism and Paleomagnetism/Marine Geology and Geophysics, ATMOSPHERIC COMPOSITION AND STRUCTURE, Air/sea constituent fluxes, Volcanic effects, BIOGEOSCIENCES, Climate dynamics, Modeling, COMPUTATIONAL GEOPHYSICS, Numerical solutions, CRYOSPHERE, Avalanches, Mass balance, GEODESY AND GRAVITY, Ocean monitoring with geodetic techniques, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Global change from geodesy, GLOBAL CHANGE, Abrupt/rapid climate change, Climate variability, Earth system modeling, Impacts of global change, Land/atmosphere interactions, Oceans, Regional climate change, Sea level change, Solid Earth, Water cycles, HYDROLOGY, Climate impacts, Hydrological cycles and budgets, INFORMATICS, MARINE GEOLOGY AND GEOPHYSICS, Gas and hydrate systems, Gravity and isostasy, ATMOSPHERIC PROCESSES, Climate change and variability, Climatology, General circulation, Ocean/atmosphere interactions, Regional modeling, Theoretical modeling, OCEANOGRAPHY], Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), ddc

Abstract

Burial driven recycling is an important process in the natural gas hydrate (GH) systems worldwide, characterized by complex multiphysics interactions like gas migration through an evolving gas hydrate stability zone (GHSZ), competing gas-water-hydrate (i.e., fluid-fluid-solid) phase transitions, locally appearing and disappearing phases, and evolving sediment properties (e.g., permeability, reaction surface area, and capillary entry pressure). Such a recycling process is typically studied in homogeneous or layered sediments. However, there is mounting evidence that structural heterogeneity and anisotropy linked to normal and inclined fault systems or anomalous sediment layers have a strong impact on the GH dynamics. Here, we consider the impacts of such a structurally complex media on the recycling process. To capture the properties of the anomalous layers accurately, we introduce a fully mass conservative, high-order, discontinuous Galerkin (DG) finite element based numerical scheme. Moreover, to handle the rapidly switching thermodynamic phase states robustly, we cast the problem of phase transitions as a set of variational inequalities, and combine our DG discretization scheme with a semi-smooth Newton solver. Here, we present our new simulator, and demonstrate using synthetic geological scenarios, (a) how the presence of an anomalous high-permeability layer, like a fracture or brecciated sediment, can alter the recycling process through flow-localization, and more importantly, (b) how an incorrect or incomplete approximation of the properties of such a layer can lead to large errors in the overall prediction of the recycling process. Key Points Structural heterogeneity linked to inclined fault systems or anomalous sediment layers have a strong impact on the gas hydrate dynamics The presence of anomalous high-permeability layers within gas hydrate stability zone alters the recycling process through flow-localization The presented discontinuous Galerkin scheme is able to accurately capture the gas hydrate recycling processes through strongly anisotropic materials

Published

2022

5. Drought Conditions Enhance Groundwater Table Fluctuations Caused by Hydropower Plant Management

Author

Basilio Hazas, M., Marcolini, G., Castagna, M., Galli, M., Singh, T., Wohlmuth, B., Chiogna, G., 1 School of Engineering and Design Technical University of Munich Munich Germany, and 2 Department of Numerical Mathematics Technical University of Munich Garching Germany

Subjects

GENERAL, Climate and interannual variability, Numerical modeling, Time series experiments, NATURAL HAZARDS, Atmospheric, Geological, Oceanic, Physical modeling, Climate impact, Risk, Disaster risk analysis and assessment, Preparedness and planning, NONLINEAR GEOPHYSICS, Probability distributions, heavy and fat-tailed, Scaling: spatial and temporal, OCEANOGRAPHY: PHYSICAL, Air/sea interactions, Decadal ocean variability, Ocean influence of Earth rotation, Sea level: variations and mean, Surface waves and tides, Tsunamis and storm surges, PALEOCEANOGRAPHY, POLICY SCIENCES, Benefit-cost analysis, Regional planning, RADIO SCIENCE, Radio oceanography, SEISMOLOGY, Earthquake ground motions and engineering seismology, Volcano seismology, SPACE PLASMA PHYSICS, Stochastic phenomena, VOLCANOLOGY, Volcano/climate interactions, Atmospheric effects, Volcano monitoring, Effusive volcanism, Mud volcanism, Explosive volcanism, Volcanic hazards and risks, Research Article, surface water-groundwater interaction, hydropower, managed rivers, groundwater modeling [ATMOSPHERIC COMPOSITION AND STRUCTURE, Air/sea constituent fluxes, Volcanic effects, BIOGEOSCIENCES, Climate dynamics, Modeling, COMPUTATIONAL GEOPHYSICS, Numerical solutions, CRYOSPHERE, Avalanches, Mass balance, GEODESY AND GRAVITY, Ocean monitoring with geodetic techniques, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Global change from geodesy, GLOBAL CHANGE, Abrupt/rapid climate change, Climate variability, Earth system modeling, Impacts of global change, Land/atmosphere interactions, Oceans, Regional climate change, Sea level change, Solid Earth, Water cycles, HYDROLOGY, Groundwater hydrology, Groundwater/surface water interaction, Time series analysis, Water management, Climate impacts, Extreme events, Hydrological cycles and budgets, INFORMATICS, Temporal analysis and representation, MARINE GEOLOGY AND GEOPHYSICS, Gravity and isostasy, MATHEMATICAL GEOPHYSICS, Persistence, memory, correlations, clustering, Stochastic processes, ATMOSPHERIC PROCESSES, Climate change and variability, Climatology, General circulation, Ocean/atmosphere interactions, Regional modeling, Theoretical modeling, OCEANOGRAPHY], groundwater modeling, ddc:551, surface water‐groundwater interaction, ddc, Water Science and Technology

Abstract

Management of hydropower plants strongly influences streamflow dynamics and hence the interaction between surface water and groundwater. As dam operations cause variations in river stages, these can result in changes in the groundwater level at multiple temporal scales. In this work, we study the case of an Alpine aquifer, where weekly fluctuations are particularly pronounced. We consider an area with four river reaches differently impacted by reservoir operations and investigate the influence of these rivers on the common aquifer. Using continuous wavelet transform and wavelet coherence analysis, we show that weekly fluctuations in the groundwater table are particularly pronounced in dry years, in particular in the winter season, although the area of the aquifer impacted by dam operations remains almost unchanged. We thus observe that in Alpine catchments, surface water‐groundwater interaction is sensitive to the conditions determined by a specific hydrological year. We also investigate the influences of the river‐aquifer water fluxes and show that under dry conditions hydropeaking mainly affects their temporal dynamics. Our observations have significant consequences for predicting nutrient and temperature dynamics/regimes in river‐aquifer systems impacted by hydropower plant management., Plain Language Summary: The operation of hydropower plants affects the water level in the downstream part of the river, which in turn can alter the groundwater level. In this work, we study an Alpine aquifer crossed by rivers differently impacted by hydropower production. We use statistical tools to analyze the interaction between the rivers and the groundwater, and observe that this interaction is sensitive to the conditions of the hydrological year, such as dry periods., Key Points: Wavelet power spectrum and coherence analysis is used to study river‐aquifer interactions under dam operations in an Alpine catchment. The impact of reservoir operations on the aquifer is strongest under low flow conditions but the area impacted shows little variation. Under low flow conditions, dam operations considerably influence the frequency of the water exchange between rivers and aquifer., Consejo Nacional de Ciencia y Tecnología http://dx.doi.org/10.13039/501100003141, Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659, Consejo Veracruzano de Investigación Científica y Desarrollo Tecnológico, https://doi.org/10.17632/97jchhz4s8.2

Published

2022

6. Trade‐Offs for Climate‐Smart Forestry in Europe Under Uncertain Future Climate

Author

Gregor, Konstantin, Knoke, Thomas, Krause, Andreas, Reyer, Christopher P. O., Lindeskog, Mats, Papastefanou, Phillip, Smith, Benjamin, Lansø, Anne‐Sofie, Rammig, Anja, 1 TUM School of Life Sciences Technical University of Munich Freising Germany, 2 Potsdam Institute for Climate Impact Research Member of the Leibniz Association Potsdam Germany, 3 Department of Physical Geography and Ecosystem Science Lund University Lund Sweden, 5 Department of Environmental Science Aarhus University Aarhus Denmark, Technische Universität München = Technical University of Munich (TUM), Potsdam Institute for Climate Impact Research (PIK), Lund University [Lund], Laboratoire des Sciences du Climat et de l'Environnement [Gif-sur-Yvette] (LSCE), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), and Aarhus University [Aarhus]

Subjects

[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, SHORT-ROTATION COPPICE, UNMANAGED FORESTS, VEGETATION DYNAMICS, climate‐smart forestry, LAND-USE, forest management, substitution effects, robust optimization, ECOSYSTEM SERVICES, climate change mitigation, ddc, CARBON SEQUESTRATION, climate-smart forestry, ddc:634.9, Earth and Planetary Sciences (miscellaneous), MANAGEMENT, ddc:630, GREENHOUSE-GAS CONCENTRATIONS, LPJ-GUESS V4.0, ecosystem services, BIOMASS PRODUCTIVITY, GENERAL, Climate and interannual variability, Numerical modeling, NATURAL HAZARDS, Atmospheric, Geological, Oceanic, Physical modeling, Climate impact, Risk, Disaster risk analysis and assessment, OCEANOGRAPHY: PHYSICAL, Air/sea interactions, Decadal ocean variability, Ocean influence of Earth rotation, Sea level: variations and mean, Surface waves and tides, Tsunamis and storm surges, PALEOCEANOGRAPHY, POLICY SCIENCES, Benefit-cost analysis, RADIO SCIENCE, Radio oceanography, SEISMOLOGY, Earthquake ground motions and engineering seismology, Volcano seismology, TECTONOPHYSICS, Evolution of the Earth, VOLCANOLOGY, Volcano/climate interactions, Atmospheric effects, Volcano monitoring, Effusive volcanism, Mud volcanism, Explosive volcanism, Volcanic hazards and risks, GEOGRAPHIC LOCATION, Europe, Research Article, robust optimization [ATMOSPHERIC COMPOSITION AND STRUCTURE, Air/sea constituent fluxes, Biosphere/atmosphere interactions, Evolution of the atmosphere, Volcanic effects, BIOGEOSCIENCES, Modeling, Climate dynamics, COMPUTATIONAL GEOPHYSICS, Numerical solutions, CRYOSPHERE, Avalanches, Mass balance, GEODESY AND GRAVITY, Ocean monitoring with geodetic techniques, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Global change from geodesy, GLOBAL CHANGE, Impacts of global change, Land/atmosphere interactions, Abrupt/rapid climate change, Atmosphere, Climate variability, Earth system modeling, Oceans, Regional climate change, Sea level change, Solid Earth, Water cycles, HYDROLOGY, Climate impacts, Hydrological cycles and budgets, INFORMATICS, MARINE GEOLOGY AND GEOPHYSICS, Gravity and isostasy, ATMOSPHERIC PROCESSES, Climate change and variability, Climatology, General circulation, Ocean/atmosphere interactions, Regional modeling, Theoretical modeling, OCEANOGRAPHY], [SDU.ENVI]Sciences of the Universe [physics]/Continental interfaces, environment, General Environmental Science

Abstract

Forests mitigate climate change by storing carbon and reducing emissions via substitution effects of wood products. Additionally, they provide many other important ecosystem services (ESs), but are vulnerable to climate change; therefore, adaptation is necessary. Climate‐smart forestry combines mitigation with adaptation, whilst facilitating the provision of many ESs. This is particularly challenging due to large uncertainties about future climate. Here, we combined ecosystem modeling with robust multi‐criteria optimization to assess how the provision of various ESs (climate change mitigation, timber provision, local cooling, water availability, and biodiversity habitat) can be guaranteed under a broad range of climate futures across Europe. Our optimized portfolios contain 29% unmanaged forests, and implicate a successive conversion of 34% of coniferous to broad‐leaved forests (11% vice versa). Coppices practically vanish from Southern Europe, mainly due to their high water requirement. We find the high shares of unmanaged forests necessary to keep European forests a carbon sink while broad‐leaved and unmanaged forests contribute to local cooling through biogeophysical effects. Unmanaged forests also pose the largest benefit for biodiversity habitat. However, the increased shares of unmanaged and broad‐leaved forests lead to reductions in harvests. This raises the question of how to meet increasing wood demands without transferring ecological impacts elsewhere or enhancing the dependence on more carbon‐intensive industries. Furthermore, the mitigation potential of forests depends on assumptions about the decarbonization of other industries and is consequently crucially dependent on the emission scenario. Our findings highlight that trade‐offs must be assessed when developing concrete strategies for climate‐smart forestry., Plain Language Summary: Forests help mitigate climate change by storing carbon and via avoided emissions when wood products replace more carbon‐intensive materials. At the same time, forests provide many other “ecosystem services (ESs)” to society. For example, they provide timber, habitat for various species, and they cool their surrounding regions. They are, however, also vulnerable to ongoing climate change. Forest management must consider all these aspects, which is particularly challenging considering the uncertainty about future climate. Here, we propose how this may be tackled by computing optimized forest management portfolios for Europe for a broad range of future climate pathways. Our results show that changes to forest composition are necessary. In particular, increased shares of unmanaged and broad‐leaved forests are beneficial for numerous ESs. However, these increased shares also lead to decreases in harvest rates, posing a conflict between wood supply and demand. We further show that the mitigation potential of forests strongly depends on how carbon‐intensive the replaced materials are. Consequently, should these materials become “greener” due to new technologies, the importance of wood products in terms of climate change mitigation decreases. Our study highlights that we cannot optimize every aspect, but that trade‐offs between ESs need to be made., Key Points: Strategies for climate‐smart forestry under a range of climate scenarios always lead to trade‐offs between different ecosystem services (ESs). Higher shares of unmanaged and broad‐leaved forests are beneficial for numerous ESs, but lead to decreased timber provision. The mitigation potential of forests strongly relies on substitution effects which depend on the carbon‐intensity of the alternative products., European Forest Institute (EFI) Networking Fund http://dx.doi.org/10.13039/501100013942, Bayerisches Staatsministerium für Wissenschaft und Kunst, Bayerisches Netzwerk für Klimaforschung (BayKliF) http://dx.doi.org/10.13039/501100004563, Swedish Research Council Formas, German Federal Office for Agriculture and Food (BLE), https://doi.org/10.5281/zenodo.6667489, https://doi.org/10.5281/zenodo.6612953

Published

2022

7. Earthquake Rupture on Multiple Splay Faults and Its Effect on Tsunamis

Author

van Zelst, I., Rannabauer, L., Gabriel, A.‐A., van Dinther, Y., 4 Department of Informatics Technical University of Munich Munich Germany, 5 Geophysics Department of Earth and Environmental Sciences LMU Munich Munich Germany, 1 Seismology and Wave Physics Institute of Geophysics, Department of Earth Sciences ETH Zürich Zürich Switzerland, and Tectonics

Subjects

ddc:551, subduction zone, numerical modelling, results, Seismic cycle related deformations, GLOBAL CHANGE, Abrupt/rapid climate change, Climate variability, Earth system modeling, Impacts of global change, Land/atmosphere interactions, Oceans, Regional climate change, Sea level change, Solid Earth, Water cycles, HYDROLOGY, Climate impacts, Estimation and forecasting, Hydrological cycles and budgets, INFORMATICS, Forecasting, IONOSPHERE, MAGNETOSPHERIC PHYSICS, MARINE GEOLOGY AND GEOPHYSICS, Gravity and isostasy, MATHEMATICAL GEOPHYSICS, Prediction, Probabilistic forecasting, ATMOSPHERIC PROCESSES, Climate change and variability, Climatology, General circulation, Ocean/atmosphere interactions, Regional modeling, Theoretical modeling, OCEANOGRAPHY: GENERAL, Climate and interannual variability, Numerical modeling, Ocean predictability and prediction, NATURAL HAZARDS, Atmospheric, Geological, Oceanic, Monitoring, forecasting, prediction, Physical modeling, Climate impact, Risk, Disaster risk analysis and assessment, OCEANOGRAPHY: PHYSICAL, Tsunamis and storm surges, Air/sea interactions, Decadal ocean variability, Ocean influence of Earth rotation, Sea level: variations and mean, Surface waves and tides, PALEOCEANOGRAPHY, POLICY SCIENCES, Benefit-cost analysis, RADIO SCIENCE, Interferometry, Ionospheric physics, Radio oceanography, SEISMOLOGY, Earthquake dynamics, Seismicity and tectonics, Subduction zones, Continental crust, Earthquake ground motions and engineering seismology, Earthquake source observations, Earthquake interaction, forecasting, and prediction, Volcano seismology, SPACE WEATHER, Policy, TECTONOPHYSICS, Dynamics: seismotectonics, VOLCANOLOGY, Volcano/climate interactions, Atmospheric effects, Volcano monitoring, Effusive volcanism, Mud volcanism, Explosive volcanism, Volcanic hazards and risks, Research Article, earthquake, tsunami, dynamic rupture, splay fault, numerical modeling [Seismology, ATMOSPHERIC COMPOSITION AND STRUCTURE, Air/sea constituent fluxes, Volcanic effects, BIOGEOSCIENCES, Climate dynamics, Modeling, COMPUTATIONAL GEOPHYSICS, Numerical solutions, CRYOSPHERE, Avalanches, Mass balance, EXPLORATION GEOPHYSICS, Gravity methods, GEODESY AND GRAVITY, Transient deformation, Tectonic deformation, Time variable gravity, Gravity anomalies and Earth structure, Ocean monitoring with geodetic techniques, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Global change from geodesy, Satellite geodesy], ddc, numerical modeling, Geophysics, Geochemistry and Petrology, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous)

Abstract

Detailed imaging of accretionary wedges reveals splay fault networks that could pose a significant tsunami hazard. However, the dynamics of multiple splay fault activation during megathrust earthquakes and the consequent effects on tsunami generation are not well understood. We use a 2‐D dynamic rupture model with complex topo‐bathymetry and six curved splay fault geometries constrained from realistic tectonic loading modeled by a geodynamic seismic cycle model with consistent initial stress and strength conditions. We find that all splay faults rupture coseismically. While the largest splay fault slips due to a complex rupture branching process from the megathrust, all other splay faults are activated either top down or bottom up by dynamic stress transfer induced by trapped seismic waves. We ascribe these differences to local non‐optimal fault orientations and variable along‐dip strength excess. Generally, rupture on splay faults is facilitated by their favorable stress orientations and low strength excess as a result of high pore‐fluid pressures. The ensuing tsunami modeled with non‐linear 1‐D shallow water equations consists of one high‐amplitude crest related to rupture on the longest splay fault and a second broader wave packet resulting from slip on the other faults. This results in two episodes of flooding and a larger run‐up distance than the single long‐wavelength (300 km) tsunami sourced by the megathrust‐only rupture. Since splay fault activation is determined by both variable stress and strength conditions and dynamic activation, considering both tectonic and earthquake processes is relevant for understanding tsunamigenesis., Plain Language Summary: In subduction zones, where one tectonic plate moves beneath another, earthquakes can occur on many different faults. Splay faults are relatively steep faults that branch off the largest fault (the megathrust) in a subduction zone. As they are steeper than the megathrust, the same amount of movement on them could result in more vertical displacement of the seafloor. Therefore, splay faults are thought to play an important role in the generation of tsunamis. Here, we use computer simulations to study if an earthquake can break multiple splay faults at once and how this affects the resulting tsunami. We find that multiple splay faults can indeed fail during a single earthquake due to the stress changes from trapped seismic waves, which promote rupture on splay faults. Rupture on splay faults results in larger seafloor displacements with smaller wavelengths, so the ensuing tsunami is bigger and results in two main flooding episodes at the coast. Our results show that it is important to consider rupture on splay faults when assessing tsunami hazard., Key Points: Multiple splay faults can be activated during a single earthquake by megathrust slip and dynamic stress transfer due to trapped waves. Splay fault activation is facilitated by their favorable orientation with respect to the local stress field and their closeness to failure. Long‐term geodynamic stresses and fault geometries affect dynamic splay fault rupture and the subsequent tsunami., Volkswagen Foundation (VolkswagenStiftung) http://dx.doi.org/10.13039/501100001663, Royal Society (The Royal Society) http://dx.doi.org/10.13039/501100000288, EC | H2020 | H2020 Priority Excellent Science | H2020 European Research Council (ERC) http://dx.doi.org/10.13039/100010663, Deutsche Forschungsgemeinschaft (DFG) http://dx.doi.org/10.13039/501100001659, National Science Foundation (NSF) http://dx.doi.org/10.13039/100000001, https://github.com/TUM-I5/SWE, https://doi.org/10.5281/zenodo.6969455

Published

2022

8. Association Between Air Pollutants and Acute Exacerbation of Chronic Obstructive Pulmonary Disease: A Time Stratified Case‐Crossover Design With a Distributed Lag Nonlinear Model

Author

Yanchen Liu, Xiaoli Han, Xudong Cui, Xiangkai Zhao, Xin Zhao, Hongmiao Zheng, Benzhong Zhang, and Xiaowei Ren

Subjects

Epidemiology, Biogeosciences, Volcanic Effects, Global Change from Geodesy, Oceanography: Biological and Chemical, Atmospheric PM2.5 in China: indoor, outdoor, and health effects, Volcanic Hazards and Risks, time‐stratified case‐crossover study, Oceans, Sea Level Change, Stochastic Phenomena, Disaster Risk Analysis and Assessment, Waste Management and Disposal, Water Science and Technology, Global and Planetary Change, Marine Pollution, Climate and Interannual Variability, Pollution, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Probability Distributions, Heavy and Fat‐tailed, Public Health, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Temporal Analysis and Representation, Megacities and Urban Environment, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Extreme Events, Geodesy and Gravity, Global Change, Time Series Analysis, Air/Sea Interactions, Numerical Modeling, Urban Systems, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, AECOPD, Water Cycles, Public Health, Environmental and Occupational Health, Modeling, Aerosols and Particles, Avalanches, Volcano Seismology, Benefit‐cost Analysis, respiratory tract diseases, distributed lag nonlinear model, air pollutants, Space Plasma Physics, Computational Geophysics, Regional Climate Change, Scaling: Spatial and Temporal, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, Pollution: Urban, Regional and Global, Surface Waves and Tides, Atmospheric Composition and Structure, Time Series Experiments, Volcano Monitoring, Seismology, Climatology, Nonlinear Geophysics, Radio Oceanography, Geohealth, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Pollution: Urban and Regional, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Persistence, Memory, Correlations, Clustering, Oceanic, Theoretical Modeling, complex mixtures, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Numerical Solutions, Climate Change and Variability, Aerosols, Stochastic Processes, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Hydrology, Sea Level: Variations and Mean

Abstract

Acute exacerbation of chronic obstruction pulmonary disease (AECOPD) as a respiratory disease, is considered to be related to air pollution by more and more studies. However, the evidence on how air pollution affect the incidence of AECOPD and whether there are population differences is still insufficient. Therefore, we select PM10, PM2.5, SO2, NO2, CO, and O3 as representatives combined with daily AECOPD admission data from 1 January 2015 to 26 June 2016 in the rural areas of Qingyang, northwestern China to explore the associations of air pollution with AECOPD. Based on a time‐stratified case‐crossover design, we constructed a distributed lag nonlinear model to qualify the single and cumulative lagged effects of air pollution on AECOPD. Stratified related risks by sex and age were also reported. The cumulative exposure‐response curves were approximately linear for PM2.5, “V”‐shaped for PM10, “U”‐shaped for NO2 and inverted‐“V” for SO2, CO and O3. Exposure to high‐PM2.5 (42 μg/m3), high‐PM10 (91 μg/m3), high‐SO2 (58 μg/m3), low‐NO2 (12 μg/m3), and high‐CO (1.55 mg/m3) increased the risk of AECOPD. Females aged 15–64 were more susceptible under extreme concentrations of PM2.5, SO2, CO, and low‐PM10 than other subgroups. In addition, adults aged 15–64 were more sensitive to extreme concentrations of NO2 compared with the elderly ≥65 years old, while the latter were more sensitive to high‐PM10. High‐SO2, high‐NO2, and extreme concentrations of PM2.5 had the greatest effects on the day of exposure, while low‐SO2 and low‐CO had lagged effects on AECOPD. Precautionary measures should be taken with a focus on vulnerable subgroups, to control hospitalization for AECOPD associated with air pollutants., Key Points Exposure to high‐PM2.5, high‐PM10, high‐SO2, low‐NO2, and high‐CO increased the risk of acute exacerbation of chronic obstruction pulmonary disease (COPD)The cumulative curves were approximately linear for PM2.5, “V”‐shaped for PM10, “U”‐shaped for NO2 and inverted‐”V” for SO2, CO and O3 The nonlinear effects on acute exacerbation of COPD at different lags varied based on the air pollutants, involved gender and age

Published

2022

9. Estimating Heat‐Related Exposures and Urban Heat Island Impacts: A Case Study for the 2012 Chicago Heatwave

Author

Kaiyu Chen, Andrew J. Newman, Mengjiao Huang, Colton Coon, Lyndsey A. Darrow, Matthew J. Strickland, and Heather A. Holmes

Subjects

Epidemiology, land surface model, Biogeosciences, Volcanic Effects, heat stress, Global Change from Geodesy, Oceanography: Biological and Chemical, Volcanic Hazards and Risks, Oceans, Sea Level Change, NWP, Disaster Risk Analysis and Assessment, Waste Management and Disposal, Water Science and Technology, Global and Planetary Change, Marine Pollution, Climate and Interannual Variability, Pollution, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Public Health, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Megacities and Urban Environment, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, TD169-171.8, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Urban Systems, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Public Health, Environmental and Occupational Health, Aerosols and Particles, Avalanches, Volcano Seismology, urban meteorology, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, excessive heat factor, Informatics, Health, Toxicology and Mutagenesis, Pollution: Urban, Regional and Global, Surface Waves and Tides, Atmospheric Composition and Structure, Environmental protection, Volcano Monitoring, Seismology, Climatology, Radio Oceanography, Geohealth, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Pollution: Urban and Regional, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Excessive Heat Factor, Risk, Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Numerical Solutions, Climate Change and Variability, Aerosols, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Hydrology, Sea Level: Variations and Mean

Abstract

Accelerated urbanization increases both the frequency and intensity of heatwaves (HW) and urban heat islands (UHIs). An extreme HW event occurred in 2012 summer that caused temperatures of more than 40°C in Chicago, Illinois, USA, which is a highly urbanized city impacted by UHIs. In this study, multiple numerical models, including the High Resolution Land Data Assimilation System (HRLDAS) and Weather Research and Forecasting (WRF) model, were used to simulate the HW and UHI, and their performance was evaluated. In addition, sensitivity testing of three different WRF configurations was done to determine the impact of increasing model complexity in simulating urban meteorology. Model performances were evaluated based on the statistical performance metrics, the application of a multi‐layer urban canopy model (MLUCM) helps WRF to provide the best performance in this study. HW caused rural temperatures to increase by ∼4°C, whereas urban Chicago had lower magnitude increases from the HW (∼2–3°C increases). Nighttime UHI intensity (UHII) ranged from 1.44 to 2.83°C during the study period. Spatiotemporal temperature fields were used to estimate the potential heat‐related exposure and to quantify the Excessive Heat Factor (EHF). The EHF during the HW episode provides a risk map indicating that while urban Chicago had higher heat‐related stress during this event, the rural area also had high risk, especially during nighttime in central Illinois. This study provides a reliable method to estimate spatiotemporal exposures for future studies of heat‐related health impacts., Key Points Extreme heatwave induced ∼4°C increase in temperature in rural Chicago while increased urban temperature by 2–3°CUrban heat island intensity is estimated to be around 1.44–2.38°CExcessive Heat Factor is higher than 50°C2 in urban Chicago due to heatwave

Published

2022

10. Anomalous Discharge of Endogenous Gas at Lavinio (Rome, Italy) and the Lethal Accident of 5 September 2011

Author

Alessandro Gattuso, Massimo Ranaldi, Franco Barberi, Tullio Ricci, M. L. Carapezza, and Luca Tarchini

Subjects

Injury control, Epidemiology, Accident prevention, lcsh:Environmental protection, Health, Toxicology and Mutagenesis, General or Miscellaneous, Volcanology, Poison control, Lavinio, Rome, Italy, Management, Monitoring, Policy and Law, Volcano Monitoring, Tsunamis and Storm Surges, Volcanic Hazards and Risks, Co2 concentration, lethal gas accident, lcsh:TD169-171.8, Instruments and Techniques, hazard from endogenous gas emission, Waste Management and Disposal, Seismology, Research Articles, Water Science and Technology, Hydrology, High concentration, Global and Planetary Change, Geological, Effusive Volcanism, Radiogenic Isotope Geochemistry, Public Health, Environmental and Occupational Health, Oxygen deficiency, Avalanches, Volcano Seismology, Pollution, Mud Volcanism, Volcanic Gases, Geochemistry, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, First person, Environmental science, Cryosphere, Natural Hazards, Oceanography: Physical, Research Article

Abstract

The Rome region contains several sites where endogenous gas is brought to the surface through deep reaching faults, creating locally hazardous conditions for people and animals. Lavinio is a touristic borough of Anzio (Rome Capital Metropolitan City) that hosts a country club with a swimming pool and an adjacent basement balance tank. In early September 2011, the pool and the tank had been emptied for cleaning. On 5 September, four men descended into the tank and immediately lost consciousness. On 12 August 2012, after a long coma the first person died, the second one reported permanent damage to his central nervous system, and the other two men recovered completely. Detailed geochemical investigations show that the site is affected by a huge release of endogenous gas (CO2 ≈ 96 vol.% and H2S ≈ 4 vol.%). High soil CO2 and H2S flux values were measured near the pool (up to 898 and 7.155 g·m−2·day−1, respectively), and a high CO2 concentration (23–25 vol.%) was found at 50–70 cm depth in the soil. We were able to demonstrate that gas had been transported into the balance tank from the swimming pool through two hubs connected to the lateral overflow channels of the pool. We show also that the time before the accident (60 hr), during which the balance tank had remained closed to external air, had been largely sufficient to reach indoor nearly lethal conditions (oxygen deficiency and high concentration of both CO2 and H2S)., Key Points In volcanic and geothermal areas, the emission of deep gas locally creates hazardous conditions for people and animals, as at LavinioLavinio country club hosts a swimming pool with a basement tank, where an accident occurred on 5 September 2011 causing the death of a manGeochemical studies show that the man inhaled a nearly lethal CO2‐H2S‐rich air mixture, transported from the pool into the basement tank

Published

2019

11. Generative Modeling of InSAR Interferograms

Author

Thomas A. Herring, Guillaume Rongier, Victor Pankratius, and Cody Rude

Subjects

Informatics, 010504 meteorology & atmospheric sciences, Computer science, lcsh:Astronomy, surface deformation, Volcanology, Technical Reports: Methods, Geostatistics, Environmental Science (miscellaneous), 010502 geochemistry & geophysics, 01 natural sciences, Volcano Monitoring, Generative modeling, Workflow, lcsh:QB1-991, Tsunamis and Storm Surges, InSAR, Volcanic Hazards and Risks, Interferometric synthetic aperture radar, geostatistics, Geodesy and Gravity, Instruments and Techniques, Seismology, 0105 earth and related environmental sciences, Remote sensing, Ground truth, Geological, Effusive Volcanism, generator, lcsh:QE1-996.5, Landslide, Avalanches, Volcano Seismology, Mud Volcanism, lcsh:Geology, machine learning, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, 13. Climate action, General Earth and Planetary Sciences, Noise (video), Cryosphere, Mathematical Geophysics, Natural Hazards, Generator (mathematics), Oceanography: Physical

Abstract

Interferometric synthetic aperture radar (InSAR) has become an essential technique to detect surface variations due to volcanoes, earthquakes, landslides, glaciers, and aquifers. However, Earth's ionosphere, atmosphere, vegetation, surface runoff, etc., introduce noise that requires post‐processing to separate its components. This work defines a generator to create interferograms that include each of those components. Our approach leverages deformation models with real data, either directly or through machine learning using geostatistical methods. These methods result from previous developments to more efficiently and better simulate spatial variables and could replace some statistical approaches used in InSAR processing. We illustrate the use of the generator to simulate an artificial interferogram based on the 2015 Illapel earthquake and discuss the improved performance offered by geostatistical approaches compared with classical statistical ones. The generator establishes a tool for multiple applications (1) to evaluate InSAR correction workflows in controlled scenarios with known ground truth; (2) to develop training sets and generative methods for machine learning algorithms; and (3) to educate on InSAR and its principles., Key Points We introduce a software tool that can generate artificial interferograms for synthetic aperture radar (SAR) applicationsThe tool leverages real data and geostatistical methods to generate and perturb interferogram componentsIt can be used to evaluate InSAR error correction workflows, to enhance machine learning use with InSAR, and to teach InSAR principles

Published

2019

12. Investigation of Forest Fire Activity Changes Over the Central India Domain Using Satellite Observations During 2001–2020

Author

Madhavi Jain, Pallavi Saxena, Som Sharma, and Saurabh Sonwani

Subjects

Epidemiology, Earthquake Source Observations, Biogeosciences, Volcanic Effects, central India, Global Change from Geodesy, Ionospheric Physics, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Waste Management and Disposal, Health and Radiation, Earthquake Interaction, Forecasting, and Prediction, Water Science and Technology, Global and Planetary Change, Gravity Methods, Climate and Interannual Variability, fire intensity, Pollution, Seismic Cycle Related Deformations, Tectonic Deformation, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Time Variable Gravity, Earth System Modeling, Atmospheric Processes, Seismicity and Tectonics, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Probabilistic Forecasting, Regional Modeling, Atmospheric Effects, Volcanology, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Earthquake Dynamics, TD169-171.8, Magnetospheric Physics, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, climate extremes, Gravity anomalies and Earth structure, Solar Physics, Astrophysics, and Astronomy, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Public Health, Environmental and Occupational Health, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, correlation, Computational Geophysics, Regional Climate Change, Subduction Zones, Transient Deformation, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, Surface Waves and Tides, Atmospheric Composition and Structure, Environmental protection, Volcano Monitoring, spatiotemporal analysis, Seismology, Climatology, Exploration Geophysics, Ocean Predictability and Prediction, Radio Oceanography, Geohealth, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Magnetic Storms, Oceanography: General, Policy, Estimation and Forecasting, Space Weather, Cryosphere, Impacts of Global Change, Coronal Mass Ejections, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, Satellite Geodesy: Results, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Ionosphere, Monitoring, Forecasting, Prediction, Numerical Solutions, Climate Change and Variability, Continental Crust, Effusive Volcanism, Climate Variability, Magnetic Storms and Substorms, forest fire count, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Interplanetary Physics, Impacts of Climate Change: Ecosystem Health, Mass Balance, Interferometry, Ocean influence of Earth rotation, Volcano/Climate Interactions, Fire in the Earth System, Hydrology, Prediction, Sea Level: Variations and Mean, Forecasting

Abstract

Recurrent and large forest fires negatively impact ecosystem, air quality, and human health. Moderate Resolution Imaging Spectroradiometer fire product is used to identify forest fires over central India domain, an extremely fire prone region. The study finds that from 2001 to 2020, ∼70% of yearly forest fires over the region occurred during March (1,857.5 counts/month) and April (922.8 counts/month). Some years such as 2009, 2012, and 2017 show anomalously high forest fires. The role of persistent warmer temperatures and multiple climate extremes in increasing forest fire activity over central India is comprehensively investigated. Warmer period from 2006 to 2020 showed doubling and tripling of forest fire activity during forest fire (February–June; FMAMJ) and non‐fire (July–January; JASONDJ) seasons, respectively. From 2015 JASONDJ to 2018 FMAMJ, central India experienced a severe heatwave, a rare drought and an extremely strong El Niño, the combined effect of which is linked to increased forest fires. Further, the study assesses quinquennial spatiotemporal changes in forest fire characteristics such as fire count density and average fire intensity. Deciduous forests of Jagdalpur‐Gadchiroli Range and Indravati National Park in Chhattisgarh state are particularly fire prone (>61 fire counts/grid) during FMAMJ and many forest fires are of high intensity (>45 MW). Statistical associations link high near surface air temperature and low precipitation during FMAMJ to significantly high soil temperature, low soil moisture content, low evapotranspiration and low normalized difference vegetation index. This creates a significantly drier environment, conducive for high forest fire activity in the region., Key Points Compared to 2001–2005, central India domain forest fire activity during 2006–2020 doubled in forest fire season and tripled in non‐fire seasonRole of persistent warmer temperatures and multiple climate extremes in increasing forest fire activity over central India is highlightedDeciduous forests of Jagdalpur‐Gadchiroli Range and Indravati National Park are extremely fire prone and fires are of high intensity

Published

2021

13. Ionospheric Corrections for Satellite Altimetry 2̆010 Impact on Global Mean Sea Level Trends

Author

Dettmering, Denise and Schwatke, Christian

Subjects

GENERAL, Ocean observing systems, Climate and interannual variability, Numerical modeling, NATURAL HAZARDS, Atmospheric, Geological, Oceanic, Physical modeling, Climate impact, Risk, Disaster risk analysis and assessment, OCEANOGRAPHY: PHYSICAL, Air/sea interactions, Decadal ocean variability, Ocean influence of Earth rotation, Sea level: variations and mean, Surface waves and tides, Tsunamis and storm surges, PALEOCEANOGRAPHY, POLICY SCIENCES, Benefit2̆010cost analysis, RADIO SCIENCE, Radio oceanography, SEISMOLOGY, Earthquake ground motions and engineering seismology, Volcano seismology, VOLCANOLOGY, Volcano/climate interactions, Atmospheric effects, Volcano monitoring, Effusive volcanism, Mud volcanism, Explosive volcanism, Volcanic hazards and risks, Research Article, satellite altimetry, sea level trend, ionosphere models [ATMOSPHERIC COMPOSITION AND STRUCTURE, Air/sea constituent fluxes, Volcanic effects, BIOGEOSCIENCES, Climate dynamics, Modeling, COMPUTATIONAL GEOPHYSICS, Numerical solutions, CRYOSPHERE, Avalanches, Mass balance, GEODESY AND GRAVITY, Ocean monitoring with geodetic techniques, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Global change from geodesy, GLOBAL CHANGE, Abrupt/rapid climate change, Climate variability, Earth system modeling, Impacts of global change, Land/atmosphere interactions, Oceans, Regional climate change, Sea level change, Solid Earth, Water cycles, HYDROLOGY, Climate impacts, Hydrological cycles and budgets, INFORMATICS, IONOSPHERE, Topside ionosphere, MARINE GEOLOGY AND GEOPHYSICS, Gravity and isostasy, ATMOSPHERIC PROCESSES, Climate change and variability, Climatology, General circulation, Ocean/atmosphere interactions, Regional modeling, Theoretical modeling, OCEANOGRAPHY], ddc

Published

2021

14. On the Detection of COVID‐Driven Changes in Atmospheric Carbon Dioxide

Author

John C. Fyfe, Nicole S. Lovenduski, Abhishek Chatterjee, David S. Schimel, Ralph F. Keeling, and Neil C. Swart

Subjects

Carbon Cycling, Biogeosciences, Volcanic Effects, Biogeochemical Kinetics and Reaction Modeling, Global Change from Geodesy, Oceanography: Biological and Chemical, Volcanic Hazards and Risks, Oceans, Sea Level Change, Growth rate, Disaster Risk Analysis and Assessment, COVID, Carbon dioxide in Earth's atmosphere, Climate and Interannual Variability, Biogeochemistry, Climate Impact, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Carbon dioxide, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Biogeochemical Cycles, Processes, and Modeling, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Hydrological Cycles and Budgets, Atmosphere, Decadal Ocean Variability, Land/Atmosphere Interactions, ocean carbon sink, Research Letter, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, large ensemble, Water Cycles, Modeling, carbon dioxide, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Tectonophysics, chemistry, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Atmospheric Science, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, Atmospheric sciences, Volcano Monitoring, chemistry.chemical_compound, land carbon sink, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Internal variability, Cryosphere, Impacts of Global Change, Oceanography: Physical, Risk, Oceanic, Theoretical Modeling, chemistry.chemical_element, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Evolution of the Earth, Climate Dynamics, carbon climate feedbacks, Earth system model, Biosphere/Atmosphere Interactions, Numerical Solutions, Evolution of the Atmosphere, Climate Change and Variability, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Surface measurement, General Earth and Planetary Sciences, Environmental science, Hydrology, Sea Level: Variations and Mean, Carbon, Understanding Carbon‐climate Feedbacks

Abstract

We assess the detectability of COVID‐like emissions reductions in global atmospheric CO2 concentrations using a suite of large ensembles conducted with an Earth system model. We find a unique fingerprint of COVID in the simulated growth rate of CO2 sampled at the locations of surface measurement sites. Negative anomalies in growth rates persist from January 2020 through December 2021, reaching a maximum in February 2021. However, this fingerprint is not formally detectable unless we force the model with unrealistically large emissions reductions (2 or 4 times the observed reductions). Internal variability and carbon‐concentration feedbacks obscure the detectability of short‐term emission reductions in atmospheric CO2. COVID‐driven changes in the simulated, column‐averaged dry air mole fractions of CO2 are eclipsed by large internal variability. Carbon‐concentration feedbacks begin to operate almost immediately after the emissions reduction; these feedbacks reduce the emissions‐driven signal in the atmosphere carbon reservoir and further confound signal detection., Key Points Climate model simulations suggest a lagged response in the global growth rate of atmospheric CO2 due to COVID‐19 emissions reductionsDetection of this reduction in observations is hampered by internal variability combined with reduced ocean and land uptake of CO2 Our results foreshadow the challenges of detecting the effects of CO2 mitigation efforts to meet the Paris climate agreement

Published

2021

15. Mapping Total Exceedance PM 2.5 Exposure Risk by Coupling Social Media Data and Population Modeling Data

Author

Zheng Cao, Zhifeng Wu, Wenchuan Guan, Hui Sun, Guanhua Guo, and Shaoying Li

Subjects

Epidemiology, Biogeosciences, Volcanic Effects, social media data, Data modeling, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Waste Management and Disposal, Water Science and Technology, Global and Planetary Change, education.field_of_study, Climate and Interannual Variability, risk assessment, Pollution, Climate Impact, population modeling data, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Public Health, Peak value, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Source data, Volcanology, total people groups, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Risk indicators, TD169-171.8, Social media, Geodesy and Gravity, Global Change, Air/Sea Interactions, education, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Public Health, Environmental and Occupational Health, exceedance PM2.5 exposure risk, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, Surface Waves and Tides, Atmospheric Composition and Structure, Environmental protection, Volcano Monitoring, Seismology, Climatology, Radio Oceanography, Geohealth, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Cryosphere, Risk assessment, Impacts of Global Change, Health Impact, Cartography, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, Population, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Environmental science, Hydrology, Sea Level: Variations and Mean

Abstract

The PM2.5 exposure risk assessment is the foundation to reduce its adverse effects. Population survey‐related data have been deficient in high spatiotemporal detailed descriptions. Social media data can quantify the PM2.5 exposure risk at high spatiotemporal resolutions. However, due to the no‐sample characteristics of social media data, PM2.5 exposure risk for older adults is absent. We proposed combining social media data and population survey‐derived data to map the total PM2.5 exposure risk. Hourly exceedance PM2.5 exposure risk indicators based on population modeling (HEPEpmd) and social media data (HEPEsm) were developed. Daily accumulative HEPEsm and HEPEpsd ranged from 0 to 0.009 and 0 to 0.026, respectively. Three peaks of HEPEsm and HEPEpsd were observed at 13:00, 18:00, and 22:00. The peak value of HEPEsm increased with time, which exhibited a reverse trend to HEPEpsd. The spatial center of HEPEsm moved from the northwest of the study area to the center. The spatial center of HEPEpsd moved from the northwest of the study area to the southwest of the study area. The expansion area of HEPEsm was nearly 1.5 times larger than that of HEPEpsd. The expansion areas of HEPEpsd aggregated in the old downtown, in which the contribution of HEPEpsd was greater than 90%. Thus, this study introduced various source data to build an easier and reliable method to map total exceedance PM2.5 exposure risk. Consequently, exposure risk results provided foundations to develop PM2.5 pollution mitigation strategies as well as scientific supports for sustainability and eco‐health achievement., Key Points Total exceedance PM2.5 exposure risk, including youths and older adults, was mappedThe hourly exceedance PM2.5 exposure risk (HEPE)psd was more aggregated than the HEPEsm Contribution of HEPEpsd varied geographically with percentage more than 50%

Published

2021

16. Resilience: Directions for an Uncertain Future Following the COVID‐19 Pandemic

Author

Igor Linkov, S. E. Galaitsi, and Margaret Kurth

Subjects

Epidemiology, Vulnerability, Biogeosciences, Volcanic Effects, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Sociology, Disaster Risk Analysis and Assessment, Robustness (economics), Waste Management and Disposal, Water Science and Technology, Covid‐19, Global and Planetary Change, Climate and Interannual Variability, Pollution, Climate Impact, climate change, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Risk analysis (engineering), Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, policy, Atmospheric Effects, 2019-20 coronavirus outbreak, Volcanology, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, TD169-171.8, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, resilience, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Public Health, Environmental and Occupational Health, Disaster Risk Communication, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Commentary, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, Surface Waves and Tides, Atmospheric Composition and Structure, Environmental protection, Volcano Monitoring, Pandemic, Disaster Resilience, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Cryosphere, Impacts of Global Change, Oceanography: Physical, Risk, Coronavirus disease 2019 (COVID-19), Oceanic, Theoretical Modeling, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Resilience (network), Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Climate Variability, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Sustainability, Hydrology, Sea Level: Variations and Mean, Disaster Management

Abstract

The concept of resilience is multi‐faceted. This commentary builds upon the analytical distinctions of resilience provided by Urquiza et al. (2021, https://doi.org/10.1029/2020EF001508). In response to this article, we emphasize several distinctions between resilience and other systems concepts. These include distinctions between resilience, risk, and vulnerability, the tradeoff between resilience and efficiency, resilience contrasted with robustness, the relationship between resilience and sustainability, and finally methods for building resilience‐by‐design or resilience‐by‐intervention. Improving understanding of these concepts will enable planners to select resilience strategies that best support their system goals. We use examples from the 2020–2021 coronavirus pandemic to illustrate the concepts and the juxtapositions between them., Key Points Resilience is one of many properties of systems affected by threat and resilience differ from robustness, sustainability, and riskBuilding resilience will require tradeoff on efficiency in complex systemsResilience can be build by design and by intervention

Published

2021

17. Evolving CO2 Rather Than SST Leads to a Factor of Ten Decrease in GCM Convergence Time

Author

Dorian S. Abbot, Jonah Bloch-Johnson, David M. Romps, and Yixiao Zhang

Subjects

Speedup, 010504 meteorology & atmospheric sciences, Planetary Atmospheres, Clouds, and Hazes, Oceanography, Biogeosciences, 01 natural sciences, Volcanic Effects, Global Change from Geodesy, Volcanic Hazards and Risks, Convergence (routing), Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Global and Planetary Change, Climate and Interannual Variability, Planetary Atmospheres, Planetary Mineralogy and Petrology, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Planetary Sciences: Comets and Small Bodies, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Composition, Global Climate Models, Atmospheric Effects, Physical geography, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Planetary Sciences: Fluid Planets, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Sea surface temperature, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Atmospheres, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, Parameter space, Volcano Monitoring, Mixing ratio, Planetary Sciences: Astrobiology, 010303 astronomy & astrophysics, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, GB3-5030, Oceanography: General, Cryosphere, Impacts of Global Change, planetary atmospheres, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, GC1-1581, Planetary Geochemistry, Radio Science, Atmospheric Sciences, Tsunamis and Storm Surges, Paleoceanography, 0103 physical sciences, Climate Dynamics, Environmental Chemistry, Planetary Sciences: Solid Surface Planets, 0105 earth and related environmental sciences, Numerical Solutions, Mineralogy and Petrology, Climate Change and Variability, Effusive Volcanism, Climate Variability, climate dynamics, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Climate Action, Mass Balance, Geochemistry, Ocean influence of Earth rotation, 13. Climate action, global climate models, Volcano/Climate Interactions, General Earth and Planetary Sciences, Environmental science, Climate sensitivity, Climate model, Hydrology, Sea Level: Variations and Mean, Order of magnitude

Abstract

The high computational cost of Global Climate Models (GCMs) is a problem that limits their use in many areas. Recently an inverse climate modeling (InvCM) method, which fixes the global mean sea surface temperature (SST) and evolves the CO2 mixing ratio to equilibrate climate, has been implemented in a cloud‐resolving model. In this article, we apply InvCM to ExoCAM GCM aquaplanet simulations, allowing the SST pattern to evolve while maintaining a fixed global‐mean SST. We find that InvCM produces the same climate as normal slab‐ocean simulations but converges an order of magnitude faster. We then use InvCM to calculate the equilibrium CO2 for SSTs ranging from 290 to 340 K at 1 K intervals and reproduce the large increase in climate sensitivity at an SST of about 315 K at much higher temperature resolution. The speedup provided by InvCM could be used to equilibrate GCMs at higher spatial resolution or to perform broader parameter space exploration in order to gain new insight into the climate system. Additionally, InvCM could be used to find unstable and hidden climate states, and to find climate states close to bifurcations such as the runaway greenhouse transition., Key Points We converge a GCM by varying the CO2 while keeping the global‐mean surface temperature fixed (the inverse climate modeling method)Inverse climate modeling converges about 10 times faster than normal slab‐ocean simulationsThe SST gradient response timescale is the bottleneck on the convergence rate of inverse climate modeling

Published

2021

18. Novel Along‐Track Processing of GRACE Follow‐On Laser Ranging Measurements Found Abrupt Water Storage Increase and Land Subsidence During the 2021 March Australian Flooding

Author

Mehdi Khaki, Eunjee Lee, Jeanne Sauber, In-Young Yeo, Shin-Chan Han, and Christopher McCullough

Subjects

Earthquake Source Observations, GPS, Debris Flow and Landslides, Track (rail transport), Biogeosciences, Volcanic Effects, Global Change from Geodesy, Ionospheric Physics, Volcanic Hazards and Risks, Geopotential Theory and Determination, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Satellite Drag, Earthquake Interaction, Forecasting, and Prediction, QE1-996.5, Gravity Methods, Water storage, Climate and Interannual Variability, Geology, flood, Seismic Cycle Related Deformations, Tectonic Deformation, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Time Variable Gravity, Earth System Modeling, Atmospheric Processes, Seismicity and Tectonics, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Probabilistic Forecasting, Regional Modeling, Atmospheric Effects, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Earthquake Dynamics, Magnetospheric Physics, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Gravity anomalies and Earth structure, Geological, Flood myth, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, Subduction Zones, Transient Deformation, Natural Hazards, Abrupt/Rapid Climate Change, Computational Methods: Potential Fields, Informatics, Astronomy, Surface Waves and Tides, Atmospheric Composition and Structure, Volcano Monitoring, Hydrological, Instruments and Techniques, Surge, Seismology, Climatology, Exploration Geophysics, Ocean Predictability and Prediction, Radio Oceanography, Flooding (psychology), Groundwater recharge, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Policy, Estimation and Forecasting, Space Weather, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, QB1-991, Satellite Geodesy: Results, Environmental Science (miscellaneous), Satellite Geodesy: Technical Issues, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, GRACE Follow‐On, Ionosphere, Monitoring, Forecasting, Prediction, Numerical Solutions, Hydrology, Climate Change and Variability, Continental Crust, Effusive Volcanism, Drought, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Floods, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Interferometry, Ocean influence of Earth rotation, Soil water, Volcano/Climate Interactions, General Earth and Planetary Sciences, Environmental science, Surface runoff, Prediction, Sea Level: Variations and Mean, Forecasting

Abstract

Following extreme drought during the 2019–2020 bushfire summer, the eastern part of Australia suffered from a week‐long intense rainfall and extensive flooding in March 2021. Understanding how much water storage changes in response to these climate extremes is critical for developing timely water management strategies. To quantify prompt water storage changes associated with the 2021 March flooding, we processed the low‐latency (1–3 days), high‐precision intersatellite laser ranging measurements from GRACE Follow‐On spacecraft and determined instantaneous gravity changes along spacecraft orbital passes. Such new data processing detected an abrupt surge of water storage approaching 60–70 trillion liters (km3 of water) over a week in the region, which concurrently caused land subsidence of ∼5 mm measured by a network of ground GPS stations. This was the highest speed of ground water recharge ever recorded in the region over the last two decades. Compared to the condition in February 2020, the amount of recharged water was similar but the recharge speed was much faster in March 2021. While these two events together replenished the region up to ∼80% of the maximum storage over the last two decades, the wet antecedent condition of soils in 2021 was distinctly different from the dry conditions in 2020 and led to generating extensive runoff and flooding in 2021., Key Points New GRACE Follow‐On gravity data processing quantified prompt changes in water storage by the heavy rainfall and flooding in March 2021The eastern Australia experienced the highest speed of ground water recharge and wet antecedent soils were responsible for extensive flooding in 2021The study demonstrated the feasibility of rapid processing (1–3 days) for immediate assessment of mass changes from extreme events

Published

2021

19. Solving Challenges of Assimilating Microwave Remote Sensing Signatures With a Physical Model to Estimate Snow Water Equivalent

Author

Ioanna Merkouriadi, Glen E. Liston, Juha Lemmetyinen, and Jouni Pulliainen

Subjects

010504 meteorology & atmospheric sciences, active microwaves, 0211 other engineering and technologies, 02 engineering and technology, Biogeosciences, Water equivalent, Volcanic Effects, 01 natural sciences, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Microwave remote sensing, Disaster Risk Analysis and Assessment, Water Science and Technology, Climate and Interannual Variability, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, snow water equivalent, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, snow modeling, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, passive microwaves, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Snow, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, Natural Hazards, Microwave, Abrupt/Rapid Climate Change, Informatics, Glaciology, Surface Waves and Tides, Atmospheric Composition and Structure, Volcano Monitoring, Remote Sensing, Snow and Ice, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Cryospheric Change, Thermodynamics, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Snow microstructure, Climate Dynamics, Numerical Solutions, Mineralogy and Petrology, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, Climate Change and Variability, Effusive Volcanism, Climate Variability, Ice, General Circulation, Policy Sciences, Climate Impacts, Snowpack, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Geochemistry, Ocean influence of Earth rotation, 13. Climate action, Volcano/Climate Interactions, Environmental science, Hydrology, Sea Level: Variations and Mean

Abstract

Global monitoring of seasonal snow water equivalent (SWE) has advanced significantly over the past decades. However, challenges remain when estimating SWE from passive and active microwave signatures, because a priori characterization of snow properties is required for SWE retrievals. Numerical experiments have shown that utilizing physical snow models to acquire snowpack characterization can potentially improve microwave‐based SWE retrievals. This study aims to identify the challenges of assimilating active and passive microwave signatures with physical snow models, and to examine solutions to those challenges. Guided by observations from a point‐based study, we designed a sensitivity experiment to quantify the effects of changes in the physically modeled SWE—and of corresponding changes to other snowpack properties—to the microwave‐based SWE retrievals. The results indicate that assimilating microwave signatures with physical snow models face some critical challenges associated with the physical relationship between SWE and snow microstructure. We demonstrate these challenges can be overcome if the microwave algorithms account for these relationships., Key Points Simulated snow properties from SnowModel are used in microwave‐based snow water equivalent (SWE) retrievals by MEMLS3&aBiases in physically modeled SWE can induce larger biases in microwave‐based SWE retrievalsThe challenges can be mitigated when microwave algorithms account for the physical relationship of snow properties

Published

2021

20. Clustering Analysis Methods for GNSS Observations: A Data‐Driven Approach to Identifying California's Major Faults

Author

Michael Heflin, Andrea Donnellan, Robert Granat, Gregory A. Lyzenga, Margaret Glasscoe, John B. Rundle, Lisa Grant Ludwig, Marlon Pierce, Jun Wang, and Jay Parker

Subjects

Earthquake Source Observations, Biogeosciences, Volcanic Effects, Global Change from Geodesy, Ionospheric Physics, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Earthquake Interaction, Forecasting, and Prediction, computer.programming_language, QE1-996.5, Gravity Methods, Climate and Interannual Variability, Geology, faults, Seismic Cycle Related Deformations, Tectonic Deformation, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Time Variable Gravity, Earth System Modeling, Atmospheric Processes, Seismicity and Tectonics, Shear zone, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Probabilistic Forecasting, Regional Modeling, Atmospheric Effects, Volcanology, Satellite system, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Earthquake Dynamics, Magnetospheric Physics, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Gravity anomalies and Earth structure, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, GNSS, Water Cycles, Modeling, Avalanches, Volcano Seismology, Python (programming language), Benefit‐cost Analysis, Tectonics, GNSS applications, earthquake, Computational Geophysics, Regional Climate Change, Subduction Zones, Transient Deformation, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Astronomy, Surface Waves and Tides, Boundary (topology), Atmospheric Composition and Structure, Volcano Monitoring, Workflow, Instruments and Techniques, Seismology, Climatology, Exploration Geophysics, Ocean Predictability and Prediction, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Geodesy, Physical Modeling, Oceanography: General, Policy, Estimation and Forecasting, Space Weather, Cryosphere, Impacts of Global Change, Oceanography: Physical, clustering, Risk, Oceanic, Theoretical Modeling, Satellite Geodesy: Results, Technical Reports: Methods, QB1-991, Environmental Science (miscellaneous), Radio Science, Data-driven, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, tectonics, Ionosphere, Monitoring, Forecasting, Prediction, Cluster analysis, Numerical Solutions, Climate Change and Variability, Continental Crust, Multihazards, Effusive Volcanism, geodetic imaging, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Machine learning for Solid Earth observation, modeling and understanding, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Interferometry, Ocean influence of Earth rotation, Volcano/Climate Interactions, General Earth and Planetary Sciences, Hydrology, Prediction, Sea Level: Variations and Mean, computer, Forecasting

Abstract

We present a data‐driven approach to clustering or grouping Global Navigation Satellite System (GNSS) stations according to observed velocities, displacements or other selected characteristics. Clustering GNSS stations provides useful scientific information, and is a necessary initial step in other analysis, such as detecting aseismic transient signals (Granat et al., 2013, https://doi.org/10.1785/0220130039). Desired features of the data can be selected for clustering, including some subset of displacement or velocity components, uncertainty estimates, station location, and other relevant information. Based on those selections, the clustering procedure autonomously groups the GNSS stations according to a selected clustering method. We have implemented this approach as a Python application, allowing us to draw upon the full range of open source clustering methods available in Python's scikit‐learn package (Pedregosa et al., 2011, https://doi.org/10.5555/1953048.2078195). The application returns the stations labeled by group as a table and color coded KML file and is designed to work with the GNSS information available from GeoGateway (Donnellan et al., 2021, https://doi.org/10.1007/s12145-020-00561-7; Heflin et al., 2020, https://doi.org/10.1029/2019ea000644) but is easily extensible. We demonstrate the methodology on California and western Nevada. The results show partitions that follow faults or geologic boundaries, including for recent large earthquakes and post‐seismic motion. The San Andreas fault system is most prominent, reflecting Pacific‐North American plate boundary motion. Deformation reflected as class boundaries is distributed north and south of the central California creeping section. For most models a cluster boundary connects the southernmost San Andreas fault with the Eastern California Shear Zone (ECSZ) rather than continuing through the San Gorgonio Pass., Key Points Unsupervised clustering methods provide a data‐driven way of analyzing and partitioning Global Navigation Satellite System observations of crustal deformationDeformation is distributed across the San Andreas fault system but is localized at the creeping section in central CaliforniaThe Southern San Andreas fault connects with the Eastern California Shear Zone rather than the rest of the San Andreas fault system

Published

2021

21. The Role of Natural Halogens in Global Tropospheric Ozone Chemistry and Budget Under Different 21st Century Climate Scenarios

Author

Alba Badia, David W. Tarasick, Carlos A. Cuevas, Jane Liu, Fernando Iglesias-Suarez, Jean-Francois Lamarque, Paul T. Griffiths, Rafael P. Fernandez, Douglas E. Kinnison, Alfonso Saiz-Lopez, Apollo-University Of Cambridge Repository, European Commission, National Science Foundation (US), Department of Energy (US), Agencia Nacional de Promoción Científica y Tecnológica (Argentina), Consejo Superior de Investigaciones Científicas (España), Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Badia, A [0000-0003-0906-8258], Iglesias-Suarez, F [0000-0003-3403-8245], Fernandez, RP [0000-0002-4114-5500], Cuevas, CA [0000-0002-9251-5460], Kinnison, DE [0000-0002-3418-0834], Lamarque, JF [0000-0002-4225-5074], Griffiths, PT [0000-0002-1089-340X], Tarasick, DW [0000-0001-9869-0692], Liu, J [0000-0001-7760-2788], Saiz-Lopez, A [0000-0002-0060-1581], and Apollo - University of Cambridge Repository

Subjects

010504 meteorology & atmospheric sciences, Radio oceanography, 01 natural sciences, 7. Clean energy, ATMOSPHERIC PROCESSES, Climate change and variability, Oceans, Earth and Planetary Sciences (miscellaneous), Cryosphere, Sea level change, Water cycle, OCEANOGRAPHY: PHYSICAL, General circulation, Regional modeling, Atmospheric effects, Hydrological cycles and budgets, Gravity and isostasy, climate change, Geophysics, RADIO SCIENCE, Global climate models, Land/atmosphere interactions, Global change from geodesy, Atmospheric, Climate impact, Mud volcanism, Volcano monitoring, MARINE GEOLOGY AND GEOPHYSICS, CRYOSPHERE, chemistry, Earthquake ground motions and engineering seismology, Effusive volcanism, HYDROLOGY, Earth System Model, Sea level: variations and mean, Tropospheric ozone, Climate variability, climate, Solid Earth, Pollutant, Tsunamis and storm surges, VOLCANOLOGY, COMPUTATIONAL GEOPHYSICS, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Atmosphere, Volcano seismology, SEISMOLOGY, Modeling, Benefit‐cost analysis, Global change, Composition and Chemistry, Avalanches, NATURAL HAZARDS, Abrupt/rapid climate change, ozone, Biosphere/atmosphere interactions, Space and Planetary Science, Greenhouse gas, Volcanic effects, Atmospheric Science, Ocean monitoring with geodetic techniques, 010501 environmental sciences, Mass balance, Atmospheric sciences, Climate dynamics, Air/sea interactions, Regional climate change, chemistry.chemical_compound, INFORMATICS, Numerical modeling, emission, Surface waves and tides, Earth system modeling, PALEOCEANOGRAPHY, Explosive volcanism, GEODESY AND GRAVITY, Climatology, Physical modeling, Decadal ocean variability, POLICY SCIENCES, Ocean/atmosphere interactions, Volcano/climate interactions, Climate and interannual variability, Impacts of global change, OCEANOGRAPHY: GENERAL, Disaster risk analysis and assessment, Research Article, Climate impacts, Risk, Ozone, Troposphere: composition and chemistry, Air/sea constituent fluxes, Oceanic, TECTONOPHYSICS, Numerical solutions, modelling, Volcanic hazards and risks, Evolution of the Earth, halogens, halogen chemistry, GLOBAL CHANGE, ATMOSPHERIC COMPOSITION AND STRUCTURE, 0105 earth and related environmental sciences, BIOGEOSCIENCES, Water cycles, Ocean influence of Earth rotation, 13. Climate action, Evolution of the atmosphere, Climate model, Theoretical modeling

Abstract

25 pags., 14 figs., 2 tabs., Tropospheric ozone ((Formula presented.)) is an important greenhouse gas and a surface pollutant. The future evolution of (Formula presented.) abundances and chemical processing are uncertain due to a changing climate, socioeconomic developments, and missing chemistry in global models. Here, we use an Earth System Model with natural halogen chemistry to investigate the changes in the (Formula presented.) budget over the 21st century following Representative Concentration Pathway (RCP)6.0 and RCP8.5 climate scenarios. Our results indicate that the global tropospheric (Formula presented.) net chemical change (NCC, chemical gross production minus destruction) will decrease (Formula presented.), notwithstanding increasing or decreasing trends in ozone production and loss. However, a wide range of surface NCC variations (from −60 (Formula presented.) to 150 (Formula presented.)) are projected over polluted regions with stringent abatements in (Formula presented.) precursor emissions. Water vapor and iodine are found to be key drivers of future tropospheric (Formula presented.) destruction, while the largest changes in (Formula presented.) production are determined by the future evolution of peroxy radicals. We show that natural halogens, currently not considered in climate models, significantly impact on the present-day and future global (Formula presented.) burden reducing (Formula presented.) 30–35 Tg (11–15 (Formula presented.)) of tropospheric ozone throughout the 21st century regardless of the RCP scenario considered. This highlights the importance of including natural halogen chemistry in climate model projections of future tropospheric ozone., EC, H2020, H2020 Priority Excellent Science, H2020 European Research Council (ERC). Grant Number: ERC-2016-COG726349; NSF, Office of Science of the US Department of Energy, PICT-2016-0714 (ANPCyT) i-COOP-B20331 (CSIC + CONICET)

Published

2021

22. Probabilistic Evaluation of Drought in CMIP6 Simulations

Author

Chandra Rupa Rajulapati, Efi Foufoula-Georgiou, Martyn P. Clark, Konstantinos M. Andreadis, Kevin E. Trenberth, and Simon Michael Papalexiou

Subjects

010504 meteorology & atmospheric sciences, 02 engineering and technology, Debris Flow and Landslides, Biogeosciences, Volcanic Effects, 01 natural sciences, Standard deviation, Physical Geography and Environmental Geoscience, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Earth and Planetary Sciences (miscellaneous), GE1-350, Hellinger distance, Disaster Risk Analysis and Assessment, QH540-549.5, General Environmental Science, reliability of climate models, droughts, Climate and Interannual Variability, Variance (accounting), Climate Impact, climate change, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, CMIP6: Trends, Interactions, Evaluation, and Impacts, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Global Climate Models, Atmospheric Effects, 0207 environmental engineering, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Geodesy and Gravity, Global Change, Precipitation, Air/Sea Interactions, Numerical Modeling, Solid Earth, CMIP6, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, 15. Life on land, Benefit‐cost Analysis, Summary statistics, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, Volcano Monitoring, Statistics, Hydrological, 020701 environmental engineering, Seismology, Climatology, Ecology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Environmental Science and Management, Theoretical Modeling, Climate change, precipitation, Radio Science, Atmospheric Sciences, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Numerical Solutions, 0105 earth and related environmental sciences, Climate Change and Variability, Effusive Volcanism, Drought, Climate Variability, Probabilistic logic, General Circulation, Policy Sciences, Climate Impacts, Floods, Mud Volcanism, Air/Sea Constituent Fluxes, Environmental sciences, Climate Action, Mass Balance, Ocean influence of Earth rotation, 13. Climate action, Volcano/Climate Interactions, Environmental science, Climate model, Hydrology, Sea Level: Variations and Mean

Abstract

As droughts have widespread social and ecological impacts, it is critical to develop long‐term adaptation and mitigation strategies to reduce drought vulnerability. Climate models are important in quantifying drought changes. Here, we assess the ability of 285 CMIP6 historical simulations, from 17 models, to reproduce drought duration and severity in three observational data sets using the Standardized Precipitation Index (SPI). We used summary statistics beyond the mean and standard deviation, and devised a novel probabilistic framework, based on the Hellinger distance, to quantify the difference between observed and simulated drought characteristics. Results show that many simulations have less than ±10% error in reproducing the observed drought summary statistics. The hypothesis that simulations and observations are described by the same distribution cannot be rejected for more than 80% of the grids based on our H distance framework. No single model stood out as demonstrating consistently better performance over large regions of the globe. The variance in drought statistics among the simulations is higher in the tropics compared to other latitudinal zones. Though the models capture the characteristics of dry spells well, there is considerable bias in low precipitation values. Good model performance in terms of SPI does not imply good performance in simulating low precipitation. Our study emphasizes the need to probabilistically evaluate climate model simulations in order to both pinpoint model weaknesses and identify a subset of best‐performing models that are useful for impact assessments., Key Points Simulations reproduce observed drought duration and severity in terms of the Standardized Precipitation Index (SPI) but simulated low precipitation is considerably biasedVariance in drought statistics among the simulations is higher in the tropics compared to other latitudinal zonesGood model performance in terms of SPI does not imply that low precipitation values are well simulated by the climate models

Published

2021

23. Lightning Geolocation and Flash Rates From LF Radio Observations During the RELAMPAGO Field Campaign

Author

Wiebke Deierling, A. Antunes de Sá, and Robert A. Marshall

Subjects

thunderstorm research, Biogeosciences, Volcanic Effects, law.invention, Global Change from Geodesy, Volcanic Hazards and Risks, detection efficiency, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, QE1-996.5, Climate and Interannual Variability, Tropical Dynamics, Geology, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Convective storm detection, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Mesoscale meteorology, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Storm, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Geolocation, Computational Geophysics, Regional Climate Change, GLM, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Astronomy, Surface Waves and Tides, Atmospheric Composition and Structure, Large Eddy Simulation, Volcano Monitoring, Convective Processes, law, Instruments and Techniques, Seismology, Climatology, Lightning detection, Data processing, RELAMPAGO, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, lightning location system, Oceanography: General, Geostationary orbit, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, VLF/LF, QB1-991, Environmental Science (miscellaneous), Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Numerical Solutions, Remote sensing, Climate Change and Variability, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Lightning, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, General Earth and Planetary Sciences, Environmental science, Hydrology, Sea Level: Variations and Mean

Abstract

The lightning data products generated by the low‐frequency (LF) radio lightning locating system (LLS) deployed during the Remote sensing of Electrification, Lightning, and Mesoscale/Microscale Processes with Adaptive Ground Observation (RELAMPAGO) field campaign in Argentina provide a valuable data set to research the lightning evolution and characteristics of convective storms that produce high‐impact weather. LF LLS data sets offer a practical range for mesoscale studies, allowing for the observation of lightning characteristics of storms such as mesoscale convective systems or large convective lines that travel longer distances which are not necessarily staying in range of regional VHF‐based lightning detection systems throughout their lifetime. LF LLSs also provide different information than optical space‐borne lightning detectors. Lightning measurements exclusive to LF systems include discharge peak current, lightning polarity, and lightning type classification based on the lightning‐emitted radio waveform. Furthermore, these measurements can provide additional information on flash rates (e.g., positive cloud‐to‐ground flash rate) or narrow bipolar events which may often be associated with dynamically intense convection. In this article, the geolocation and data processing of the LF data set collected during RELAMPAGO is fully described and its performance characterized, with location accuracy better than 10 km. The detection efficiency (DE) of the data set is compared to that of the Geostationary Lightning Mapper, and spatiotemporal DE losses in the LF data set are discussed. Storm case studies on November 10, 2018, highlight the strengths of the data set, which include robust flash clustering and insightful flash rate and peak current measures, while illustrating how its limitations, including DE losses, can be managed., Key Points Geolocation and processing of the low‐frequency (LF) data set collected during the Remote sensing of Electrification, Lightning, and Mesoscale/Microscale Processes with Adaptive Ground Observation campaign is fully described and characterizedUnique LF observations include discharge peak current, polarity, and possibly type classification based on the emitted radio waveformLF spatiotemporal detection efficiency and storm case studies are discussed and compared to Geostationary Lightning Mapper data

Published

2021

24. Multiscale Assessment of Agricultural Consumptive Water Use in California's Central Valley

Author

A. J. Wong, Y. Jin, J. Medellín‐Azuara, K. T. Paw U, E. R. Kent, J. M. Clay, F. Gao, J. B. Fisher, G. Rivera, C. M. Lee, K. S. Hemes, E. Eichelmann, D. D. Baldocchi, and S. J. Hook

Subjects

Space Geodetic Surveys, Biogeosciences, Volcanic Effects, Physical Geography and Environmental Geoscience, Global Change from Geodesy, Volcanic Hazards and Risks, Regional Planning, Evapotranspiration, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Water Budgets, Water Science and Technology, geography.geographical_feature_category, Climate and Interannual Variability, Remote Sensing and Disasters, Spatial heterogeneity, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, latent heat flux, Earth System Modeling, Atmospheric Processes, Zero Hunger, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Environmental Engineering, Water Management, Life on Land, Volcanology, Hydrological Cycles and Budgets, Crop, Decadal Ocean Variability, Land/Atmosphere Interactions, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Agriculture, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, crop water consumptive use, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, AmeriFlux, Pasture, Volcano Monitoring, Remote Sensing, Consumptive water use, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, precision irrigation, Theoretical Modeling, Civil Engineering, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Farm water, Remote Sensing of Volcanoes, Numerical Solutions, Climate Change and Variability, Hydrology, geography, Effusive Volcanism, Land use, surface energy balance, business.industry, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Environmental science, Preparedness and Planning, Sea Level: Variations and Mean, business

Abstract

Spatial estimates of crop evapotranspiration with high accuracy from the field to watershed scale have become increasingly important for water management, particularly over irrigated agriculture in semiarid regions. Here, we provide a comprehensive assessment on patterns of annual agricultural water use over California's Central Valley, using 30‐m daily evapotranspiration estimates based on Landsat satellite data. A semiempirical Priestley‐Taylor approach was locally optimized and cross‐validated with available field measurements for major crops including alfalfa, almond, citrus, corn, pasture, and rice. The evapotranspiration estimates explained >70% variance in daily measurements from independent sites with an RMSE of 0.88 mm day−1. When aggregated over the Valley, we estimated an average evapotranspiration of 820 ± 290 mm yr−1 in 2014. Agricultural water use varied significantly across and within crop types, with a coefficient of variation ranging from 8% for Rice (1,110 ± 85 mm yr−1) to 59% for Pistachio (592 ± 352 mm yr−1). Total water uses in 2016 increased by 9.6%, as compared to 2014, mostly because of land‐use conversion from fallow/idle land to cropland. Analysis across 134 Groundwater Sustainability Agencies (GSAs) further showed a large variation of agricultural evapotranspiration among and within GSAs, especially for tree crops, e.g., almond evapotranspiration ranging from 339 ± 80 mm yr−1 in Tracy to 1,240 ± 136 mm yr−1 in Tri‐County Water Authority. Continuous monitoring and assessment of the dynamics and spatial heterogeneity of agricultural evapotranspiration provide data‐driven guidance for more effective land use and water planning across scales., Key Points A 30‐m daily evapotranspiration product estimated using regionally optimized approach and Landsat Analysis Ready Data Collection 1Assessment of agricultural consumptive water use over Central Valley provides critical guidance for sustainable groundwater managementLarge variation of water use was found, mostly due to crop diversity, age structure, and physiological factors

Published

2021

25. Human Mobility to Parks under the COVID-19 Pandemic and Wildfire Seasons in the Western and Central United States

Author

Jue Yang, Anni Yang, Rongting Xu, Yaqian He, Di Yang, Han Qiu, and Amanda Aragon

Subjects

Epidemiology, Air pollution, Biogeosciences, Volcanic Effects, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Per capita, Stochastic Phenomena, Socioeconomics, Disaster Risk Analysis and Assessment, Waste Management and Disposal, Water Science and Technology, Global and Planetary Change, Social distance, Climate and Interannual Variability, COVID‐19 pandemic, Pollution, Climate Impact, Geography, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Probability Distributions, Heavy and Fat‐tailed, Public Health, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Temporal Analysis and Representation, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Extreme Events, Natural hazard, TD169-171.8, Geodesy and Gravity, Global Change, Time Series Analysis, Air/Sea Interactions, Recreation, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Public Health, Environmental and Occupational Health, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, park visitation, smoke, Space Plasma Physics, Computational Geophysics, Regional Climate Change, Scaling: Spatial and Temporal, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, Surface Waves and Tides, Atmospheric Composition and Structure, Time Series Experiments, medicine.disease_cause, Environmental protection, Volcano Monitoring, wildfire, Human health, Pandemic, Seismology, Climatology, Nonlinear Geophysics, Radio Oceanography, Geohealth, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Impacts of Climate Change: Human Health, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Persistence, Memory, Correlations, Clustering, Coronavirus disease 2019 (COVID-19), Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, medicine, human mobility, Numerical Solutions, Climate Change and Variability, Stochastic Processes, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Hydrology, Sea Level: Variations and Mean, human activities

Abstract

In 2020, people's health suffered a great crisis under the dual effects of the COVID‐19 pandemic and the extensive, severe wildfires in the western and central United States. Parks, including city, national, and cultural parks, offer a unique opportunity for people to maintain their recreation behaviors following the social distancing protocols during the pandemic. However, massive forest wildfires in western and central US, producing harmful toxic gases and smoke, pose significant threats to human health and affect their recreation behaviors and mobility to parks. In this study, we employed the geographically and temporally weighted regression (GTWR) Models to investigate how COVID‐19 and wildfires jointly shaped human mobility to parks, regarding the number of visits per capita, dwell time, and travel distance to parks, during June ‐ September 2020. We detected strong correlations between visitations and COVID‐19 incidence in southern Montana, western Wyoming, Colorado, and Utah before August. However, the pattern was weakened over time, indicating the decreasing trend of the degree of concern regarding the pandemic. Moreover, more park visits and lower dwell time were found in parks further away from wildfires and less air pollution in Washington, Oregon, California, Colorado, and New Mexico, during the wildfire season, suggesting the potential avoidance of wildfires when visiting parks. This study provides important insights on people's responses in recreation and social behaviors when facing multiple severe crises that impact their health and wellbeing, which could support the preparation and mitigation of the health impacts from future pandemics and natural hazards., Key Points We investigated human mobility patterns to parks under COVID‐19 pandemic and wildfire season in western and central United StatesWe found a general trend of avoidance to the parks with fewer visits and dwell time in the places with high COVID‐19 casesWith special demand of physical activities in pandemic, people travel further and spend longer time at the parks away from the wildfires

Published

2021

26. A Generalized Interpolation Material Point Method for Shallow Ice Shelves. 2: Anisotropic Nonlocal Damage Mechanics and Rift Propagation

Author

A. Huth, Ben Smith, and Ravindra Duddu

Subjects

Modeling in Glaciology, Oceanography, Biogeosciences, Volcanic Effects, Ice shelf, Global Change from Geodesy, Volcanic Hazards and Risks, Damage mechanics, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Global and Planetary Change, geography.geographical_feature_category, Climate and Interannual Variability, Mechanics, Dynamics, Climate Impact, Damage, Ice Streams, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Physical geography, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Crevasse, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Ice Shelves, Fracture (geology), Computational Geophysics, Regional Climate Change, Natural Hazards, Necking, Abrupt/Rapid Climate Change, Informatics, Glaciology, Ice stream, Surface Waves and Tides, Atmospheric Composition and Structure, Volcano Monitoring, Snow and Ice, particle method, Snow, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, GB3-5030, Oceanography: General, Creep, Cryospheric Change, Cryosphere, Impacts of Global Change, Geology, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, material point method, GC1-1581, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Environmental Chemistry, Numerical Solutions, Climate Change and Variability, geography, Effusive Volcanism, Climate Variability, Ice, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, fracture, Volcano/Climate Interactions, General Earth and Planetary Sciences, Hydrology, Ice sheet, Sea Level: Variations and Mean

Abstract

Ice shelf fracture is responsible for roughly half of Antarctic ice mass loss in the form of calving and can weaken buttressing of upstream ice flow. Large uncertainties associated with the ice sheet response to climate variations are due to a poor understanding of these fracture processes and how to model them. Here, we address these problems by implementing an anisotropic, nonlocal integral formulation of creep damage within a large‐scale shallow‐shelf ice flow model. This model can be used to study the full evolution of fracture from initiation of crevassing to rifting that eventually causes tabular calving. While previous ice shelf fracture models have largely relied on simple expressions to estimate crevasse depths, our model parameterizes fracture as a progressive damage evolution process in three‐dimensions (3‐D). We also implement an efficient numerical framework based on the material point method, which avoids advection errors. Using an idealized marine ice sheet, we test the creep damage model and a crevasse‐depth based damage model, including a modified version of the latter that accounts for damage evolution due to necking and mass balance. We demonstrate that the creep damage model is best suited for capturing weakening and rifting over shorter (monthly/yearly) timescales, and that anisotropic damage reproduces typically observed fracture patterns better than isotropic damage. Because necking and mass balance can significantly influence damage on longer (decadal) timescales, we discuss the potential for a combined approach between models to best represent mechanical weakening and tabular calving within long‐term simulations., Key Points Our shallow‐shelf creep damage model can represent the full evolution of ice shelf fracture from crevasse initiation to tabular calvingStrongly anisotropic creep damage produces sharp, arcuate rift patterns more consistent with observations than isotropic creep damageThe zero‐stress damage model poorly captures rifting, but a modified form accounts for damage evolution due to mass balance and necking

Published

2021

27. Accurate Simulation of Both Sensitivity and Variability for Amazonian Photosynthesis: Is It Too Much to Ask?

Author

Nicholas M. Geyer, Sarah M. Gallup, Natalia Restrepo-Coupe, John Luke Gallup, Ian Baker, A. Scott Denning, and Katherine D. Haynes

Subjects

Amazonian, Reference data (financial markets), Oceanography, Biogeosciences, Volcanic Effects, Biogeochemical Kinetics and Reaction Modeling, Global Change from Geodesy, Oceanography: Biological and Chemical, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Global and Planetary Change, Climate and Interannual Variability, Variance (accounting), Biogeochemistry, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Biogeochemical Cycles, Processes, and Modeling, Atmospheric, Regional Modeling, Atmospheric Effects, Physical geography, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Sensitivity (control systems), Geodesy and Gravity, Global Change, model benchmarking, Air/Sea Interactions, Numerical Modeling, Amazon, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, variability, Water Cycles, Modeling, Avalanches, Volcano Seismology, medicine.disease, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, tropical rainforest, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, Atmospheric sciences, Volcano Monitoring, Instruments and Techniques, Seismology, Climatology, gross primary productivity (GPP), Radio Oceanography, seasonality, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, GB3-5030, Oceanography: General, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, Eddy covariance, Climate change, GC1-1581, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, medicine, Environmental Chemistry, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Seasonality, Climate Impacts, Confidence interval, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, General Earth and Planetary Sciences, Environmental science, 0401 Atmospheric Sciences, Hydrology, Sea Level: Variations and Mean

Abstract

Estimates of Amazon rainforest gross primary productivity (GPP) differ by a factor of 2 across a suite of three statistical and 18 process models. This wide spread contributes uncertainty to predictions of future climate. We compare the mean and variance of GPP from these models to that of GPP at six eddy covariance (EC) towers. Only one model's mean GPP across all sites falls within a 99% confidence interval for EC GPP, and only one model matches EC variance. The strength of model response to climate drivers is related to model ability to match the seasonal pattern of the EC GPP. Models with stronger seasonal swings in GPP have stronger responses to rain, light, and temperature than does EC GPP. The model to data comparison illustrates a trade‐off inherent to deterministic models between accurate simulation of a mean (average) and accurate responsiveness to drivers. The trade‐off exists because all deterministic models simplify processes and lack at least some consequential driver or interaction. If a model's sensitivities to included drivers and their interactions are accurate, then deterministically predicted outcomes have less variability than is realistic. If a GPP model has stronger responses to climate drivers than found in data, model predictions may match the observed variance and seasonal pattern but are likely to overpredict GPP response to climate change. High or realistic variability of model estimates relative to reference data indicate that the model is hypersensitive to one or more drivers., Key Points Regression logic is reason to doubt the accurate climate sensitivity of predictions whose variability is realistic or higherA suite of models poorly reproduces eddy covariance estimates of Amazon rainforest gross primary productivityHighly seasonal models predict stronger primary productivity responsiveness to meteorology than is likely to be true

Published

2021

28. A Generalized Interpolation Material Point Method for Shallow Ice Shelves. 1: Shallow Shelf Approximation and Ice Thickness Evolution

Author

Ravindra Duddu, A. Huth, and Ben Smith

Subjects

State variable, Modeling in Glaciology, Biogeosciences, Oceanography, Volcanic Effects, Ice shelf, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Global and Planetary Change, geography.geographical_feature_category, Climate and Interannual Variability, Finite element method, Dynamics, Climate Impact, Ice Streams, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Interpolation, Atmospheric Effects, Physical geography, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Ice stream, Surface Waves and Tides, Geometry, Atmospheric Composition and Structure, Volcano Monitoring, Snow and Ice, particle method, Snow, ice shelves, Material point method, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, GB3-5030, Oceanography: General, Cryospheric Change, Cryosphere, Impacts of Global Change, damage, Geology, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, material point method, GC1-1581, Weak formulation, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, glaciology, Environmental Chemistry, Numerical Solutions, Climate Change and Variability, geography, Effusive Volcanism, Climate Variability, Ice, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Glaciology, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, fracture, Volcano/Climate Interactions, General Earth and Planetary Sciences, Hydrology, Sea Level: Variations and Mean

Abstract

We develop a generalized interpolation material point method (GIMPM) for the shallow shelf approximation (SSA) of ice flow. The GIMPM, which can be viewed as a particle version of the finite element method, is used here to solve the shallow shelf approximations of the momentum balance and ice thickness evolution equations. We introduce novel numerical schemes for particle splitting and integration at domain boundaries to accurately simulate the spreading of an ice shelf. The advantages of the proposed GIMPM‐SSA framework include efficient advection of history or internal state variables without diffusion errors, automated tracking of the ice front and grounding line at sub‐element scales, and a weak formulation based on well‐established conventions of the finite element method with minimal additional computational cost. We demonstrate the numerical accuracy and stability of the GIMPM using 1‐D and 2‐D benchmark examples. We also compare the accuracy of the GIMPM with the standard material point method (sMPM) and a reweighted form of the sMPM. We find that the grid‐crossing error is very severe for SSA simulations with the sMPM, whereas the GIMPM successfully mitigates this error. While the grid‐crossing error can be reasonably reduced in the sMPM by implementing a simple material point reweighting scheme, this approach it not as accurate as the GIMPM. Thus, we illustrate that the GIMPM‐SSA framework is viable for the simulation of ice sheet‐shelf evolution and enables boundary tracking and error‐free advection of history or state variables, such as ice thickness or damage., Key Points Our material point method for ice shelf flow enables error‐free advection of history variables, such as damage, and ice front trackingThe method can be readily implemented into existing finite element software (here, Elmer/Ice), and is suitable for large‐scale applicationThe method is verified against analytical solutions for steady‐state flow and front evolution, and tested on an idealized marine ice sheet

Published

2021

29. Implementation and Impacts of Surface and Blowing Snow Sources of Arctic Bromine Activation Within WRF‐Chem 4.1.1

Author

Jennie L. Thomas, Louis Marelle, Foteini Baladima, Katie Tuite, Markus M. Frey, Aurélien Dommergue, Shaddy Ahmed, William R. Simpson, Jochen Stutz, Institut des Géosciences de l’Environnement (IGE), Université Grenoble Alpes (UGA)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Institut de Recherche pour le Développement (IRD)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA), TROPO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), Department of Atmospheric and Oceanic Sciences [Los Angeles] (AOS), University of California [Los Angeles] (UCLA), University of California-University of California, Geophysical Institute [Fairbanks], University of Alaska [Fairbanks] (UAF), British Antarctic Survey (BAS), Natural Environment Research Council (NERC), This work also supported by the CNRS INSU LEFE-CHAT program under the grant Brom-Arc. We acknowledge support for William R. Simpson from the National Science Foundation grant ARC-1602716. This work was performed using HPC resources from GENCI-IDRIS (Grant A007017141) and the IPSL mesoscale computing center (CICLAD: Calcul Intensif pour le CLi-mat, l'Atmosphère et la Dynamique). We thank the WRF-Chem development and support teams at NOAA, NCAR, and PNNL for their support and collaborations. We acknowledge NCAR ACOM for providing the WRF-Chem chemical boundary conditions used in this study. We acknowledge use of the WRF-Chem pre-processor tools provid-ed by the Atmospheric Chemistry Ob-servations and Modeling Lab (ACOM) of NCAR. We acknowledge the NOAA Global Monitoring Laboratory Earth System Research Laboratories and the O-Buoy program for providing obser-vations used in this study., Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), and University of California (UC)-University of California (UC)

Subjects

atmospheric chemistry, 010504 meteorology & atmospheric sciences, Oceanography, Biogeosciences, Volcanic Effects, 01 natural sciences, Global Change from Geodesy, Oceanography: Biological and Chemical, Volcanic Hazards and Risks, Constituent Sources and Sinks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Blowing snow, [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, Global and Planetary Change, geography.geographical_feature_category, aerosol chemistry, Marine Pollution, Climate and Interannual Variability, Ozone depletion, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, arctic ozone, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Physical geography, Volcanology, Megacities and Urban Environment, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, food, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Urban Systems, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Sea salt, Modeling, Aerosols and Particles, Avalanches, Volcano Seismology, Snow, Benefit‐cost Analysis, snow emissions, chemistry, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Pollution: Urban, Regional and Global, Surface Waves and Tides, Atmospheric Composition and Structure, 010501 environmental sciences, Atmospheric sciences, Volcano Monitoring, chemistry.chemical_compound, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, GB3-5030, Oceanography: General, Pollution: Urban and Regional, Atmospheric chemistry, Troposphere: Composition and Chemistry, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Ozone, food.ingredient, Oceanic, Theoretical Modeling, GC1-1581, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Sea ice, halogen chemistry, Environmental Chemistry, Numerical Solutions, 0105 earth and related environmental sciences, Climate Change and Variability, Aerosols, geography, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Arctic, 13. Climate action, Volcano/Climate Interactions, General Earth and Planetary Sciences, Hydrology, Sea Level: Variations and Mean

Abstract

Elevated concentrations of atmospheric bromine are known to cause ozone depletion in the Arctic, which is most frequently observed during springtime. We implement a detailed description of bromine and chlorine chemistry within the WRF‐Chem 4.1.1 model, and two different descriptions of Arctic bromine activation: (1) heterogeneous chemistry on surface snow on sea ice, triggered by ozone deposition to snow (Toyota et al., 2011 https://doi.org/10.5194/acp-11-3949-2011), and (2) heterogeneous reactions on sea salt aerosols emitted through the sublimation of lofted blowing snow (Yang et al., 2008, https://doi.org/10.1029/2008gl034536). In both mechanisms, bromine activation is sustained by heterogeneous reactions on aerosols and surface snow. Simulations for spring 2012 covering the entire Arctic reproduce frequent and widespread ozone depletion events, and comparisons with observations of ozone show that these developments significantly improve model predictions during the Arctic spring. Simulations show that ozone depletion events can be initiated by both surface snow on sea ice, or by aerosols that originate from blowing snow. On a regional scale, in spring 2012, snow on sea ice dominates halogen activation and ozone depletion at the surface. During this period, blowing snow is a major source of Arctic sea salt aerosols but only triggers a few depletion events., Key Points Halogen activation and its role in Arctic surface ozone depletion events (ODEs) is modeled using WRF‐ChemTwo halogen activation mechanisms are implemented (1) surface snow and (2) blowing snowA spring 2012 case study indicates that both mechanisms can trigger near‐surface ODEs, but that surface snow dominates

Published

2021

30. Unknown eruption source parameters cause large uncertainty in historical volcanic radiative forcing reconstructions

Author

Lindsay Lee, Richard Rigby, Kenneth S. Carslaw, Anja Schmidt, Graham Mann, Lauren Marshall, Jill S. Johnson, Marshall, LR [0000-0003-1471-9481], Schmidt, A [0000-0001-8759-2843], Mann, GW [0000-0003-1746-2837], Lee, LA [0000-0002-8029-6328], Rigby, R [0000-0001-9554-6054], Carslaw, KS [0000-0002-6800-154X], Apollo - University of Cambridge Repository, Marshall, Lauren R. [0000-0003-1471-9481], Schmidt, Anja [0000-0001-8759-2843], Mann, Graham W. [0000-0003-1746-2837], Lee, Lindsay A. [0000-0002-8029-6328], Rigby, Richard [0000-0001-9554-6054], and Carslaw, Ken S. [0000-0002-6800-154X]

Subjects

010504 meteorology & atmospheric sciences, Radio oceanography, Forcing (mathematics), 01 natural sciences, statistical emulation, ATMOSPHERIC PROCESSES, Climate change and variability, Oceans, Earth and Planetary Sciences (miscellaneous), Sea level change, OCEANOGRAPHY: PHYSICAL, geography.geographical_feature_category, General circulation, Regional modeling, Atmospheric effects, sulfate deposition, Hydrological cycles and budgets, Gravity and isostasy, volcanic eruptions, Geophysics, RADIO SCIENCE, volcanic radiative forcing, Land/atmosphere interactions, Global change from geodesy, Atmospheric, Climate impact, Mud volcanism, Volcano monitoring, MARINE GEOLOGY AND GEOPHYSICS, CRYOSPHERE, Earthquake ground motions and engineering seismology, Effusive volcanism, HYDROLOGY, Sulfate aerosol, Sea level: variations and mean, Sulfate, Climate variability, Solid Earth, Tsunamis and storm surges, VOLCANOLOGY, Explosive eruption, COMPUTATIONAL GEOPHYSICS, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Volcano seismology, SEISMOLOGY, Modeling, Benefit‐cost analysis, Radiative forcing, Avalanches, NATURAL HAZARDS, Abrupt/rapid climate change, chemistry, Space and Planetary Science, Volcanic effects, volcanic aerosol, Atmospheric Science, Ocean monitoring with geodetic techniques, Mass balance, Atmospheric sciences, Climate dynamics, Air/sea interactions, Regional climate change, chemistry.chemical_compound, Ice core, INFORMATICS, Numerical modeling, Radiative transfer, Surface waves and tides, Earth system modeling, PALEOCEANOGRAPHY, Explosive volcanism, GEODESY AND GRAVITY, Climatology, Physical modeling, Decadal ocean variability, POLICY SCIENCES, Ocean/atmosphere interactions, Volcano/climate interactions, Climate and interannual variability, Impacts of global change, OCEANOGRAPHY: GENERAL, Disaster risk analysis and assessment, Research Article, Climate impacts, Risk, Air/sea constituent fluxes, Oceanic, Numerical solutions, Volcanic hazards and risks, GLOBAL CHANGE, ATMOSPHERIC COMPOSITION AND STRUCTURE, 0105 earth and related environmental sciences, geography, BIOGEOSCIENCES, Water cycles, Volcano, Ocean influence of Earth rotation, Environmental science, Theoretical modeling

Abstract

Funder: U.K. China Research and Innovation Partnership Fund, Funder: National Centre for Atmospheric Science (NCAS); Id: http://dx.doi.org/10.13039/501100000662, Reconstructions of volcanic aerosol radiative forcing are required to understand past climate variability. Currently, reconstructions of pre‐20th century volcanic forcing are derived from sulfate concentrations measured in polar ice cores, mainly using a relationship between the average ice‐sheet sulfate deposition and stratospheric sulfate aerosol burden based on a single explosive eruption—the 1991 eruption of Mt. Pinatubo. Here we estimate volcanic radiative forcings and associated uncertainty ranges from ice‐core sulfate records of eight of the largest bipolar deposition signals in the last 2,500 years using statistical emulation of a perturbed parameter ensemble of aerosol‐climate model simulations of explosive eruptions. Extensive sampling of different combinations of eruption source parameters using the emulators reveals that a very wide range of eruptions in different seasons with different sulfur dioxide emissions, eruption latitudes, and emission altitudes produce ice‐sheet sulfate deposition consistent with ice‐core records. Consequently, we find a large range in the volcanic forcing that can be directly attributed to the unknown eruption source parameters. We estimate that the uncertainty in volcanic forcing caused by many plausible eruption realizations leads to uncertainties in the global mean surface cooling of around 1°C for the largest unidentified historical eruptions. Our emulators are available online (https://cemac.github.io/volcanic-forcing-deposition) where eruption realizations for given ice‐sheet sulfate depositions can be explored.

Published

2021

31. Reducing Planetary Health Risks Through Short‐Lived Climate Forcer Mitigation

Author

Yiqi Zheng and Nadine Unger

Subjects

Epidemiology, Air pollution, Biogeosciences, Volcanic Effects, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Waste Management and Disposal, Water Science and Technology, Global and Planetary Change, Climate and Interannual Variability, Pollution, Climate Impact, climate change, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Public Health, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, PM2.5, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, TD169-171.8, Ecosystem, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Thermosphere: Composition and Chemistry, Modeling, Public Health, Environmental and Occupational Health, Avalanches, Volcano Seismology, Radiative forcing, Benefit‐cost Analysis, Agriculture, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Natural resource economics, Health, Toxicology and Mutagenesis, Surface Waves and Tides, Atmospheric Composition and Structure, human health, medicine.disease_cause, Environmental protection, Volcano Monitoring, Global health, Seismology, Climatology, Radio Oceanography, Geohealth, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, air quality, Oceanography: General, Impacts of Climate Change: Human Health, Cryosphere, premature deaths, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, Climate change, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, medicine, Air quality index, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, radiative forcing, business.industry, Climate Variability, Global warming, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Environmental science, Hydrology, Sea Level: Variations and Mean, business

Abstract

Global air pollution and climate change are major threats to planetary health. These threats are strongly linked through the short‐lived climate forcers (SLCFs); ozone (O3), aerosols, and methane (CH4). Understanding the impacts of ambitious SLCF mitigation in different source emission sectors on planetary health indicators can help prioritize international air pollution control strategies. A global Earth system model is applied to quantify the impacts of idealized 50% sustained reductions in year 2005 emissions in the eight largest global anthropogenic source sectors on the SLCFs and three indicators of planetary health: global mean surface air temperature change (∆GSAT), avoided PM2.5‐related premature mortalities and gross primary productivity (GPP). The model represents fully coupled atmospheric chemistry, aerosols, land ecosystems and climate, and includes dynamic CH4. Avoided global warming is modest, with largest impacts from 50% cuts in domestic (−0.085 K), agriculture (−0.034 K), and waste/landfill (−0.033 K). The 50% cuts in energy, domestic, and agriculture sector emissions offer the largest opportunities to mitigate global PM2.5‐related health risk at around 5%–7% each. Such small global impacts underline the challenges ahead in achieving the World Health Organization aspirational goal of a 2/3 reduction in the number of deaths from air pollution by 2030. Uncertainty due to natural climate variability in PM2.5 is an important underplayed dimension in global health risk assessment that can vastly exceed uncertainty due to the concentration‐response functions at the large regional scale. Globally, cuts to agriculture and domestic sector emissions are the most attractive targets to achieve climate and health co‐benefits through SLCF mitigation., Key Points Quantify impacts of deep short‐lived climate forcer (SLCF) emission mitigation by source sector on global temperature and human and ecosystem healthUncertainties due to year‐to‐year meteorological variability in PM2.5 is an important dimension in global human health risk assessmentAchieving planetary health benefits from SLCF mitigation requires ambitious mitigation pathways that tackle multiple source sectors

Published

2021

32. Towards Wind Vector and Wave Height Retrievals Over Inland Waters Using CYGNSS

Author

Eric Loria, Cinzia Zuffada, Valery U. Zavorotny, and Andrew O'Brien

Subjects

Space Geodetic Surveys, Abrupt/Rapid Climate Change, Informatics, Astronomy, Surface Waves and Tides, Atmospheric Composition and Structure, Biogeosciences, Volcanic Effects, Wind speed, Volcano Monitoring, Remote Sensing, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Surface roughness, River Channels, Disaster Risk Analysis and Assessment, Seismology, Climatology, QE1-996.5, Radio Oceanography, Climate and Interannual Variability, Remote Sensing and Disasters, Geology, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Surface wave, Earth System Modeling, Atmospheric Processes, Cryosphere, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Impacts of Global Change, Atmospheric, Regional Modeling, Oceanography: Physical, Research Article, Risk, Atmospheric Effects, Meteorology, Oceanic, Theoretical Modeling, Climate change, Volcanology, QB1-991, Environmental Science (miscellaneous), Hydrological Cycles and Budgets, Radio Science, Tsunamis and Storm Surges, Decadal Ocean Variability, Land/Atmosphere Interactions, Paleoceanography, Rivers, Wave height, Climate Dynamics, Remote Sensing of Volcanoes, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Numerical Solutions, Climate Change and Variability, Geological, Effusive Volcanism, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Climate Variability, Water Cycles, Modeling, Sediment, Riparian Systems, General Circulation, Policy Sciences, Avalanches, Climate Impacts, Volcano Seismology, Benefit‐cost Analysis, Mud Volcanism, Wind wave model, GNSS reflectometry, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, General Earth and Planetary Sciences, Environmental science, Computational Geophysics, Regional Climate Change, Hydrology, Sea Level: Variations and Mean, Natural Hazards

Abstract

GNSS Reflectometry (GNSS‐R) measurements over inland water bodies, such as lakes, rivers, and wetlands exhibit strong coherent signals. The strength of the coherent reflections is highly sensitive to small‐scale surface roughness. For inland waters, this roughness is primarily due to wind‐driven surface waves. The sensitivity of the coherent reflections to surface roughness can be leveraged to estimate wave height profiles across inland waters. Coupled with a wind wave model, an approach to retrieve a wind vector is described using a forward model, which is potentially able to predict scattered power profiles for different wind speeds and directions and choosing the minimum‐squared error solution. The ability for spaceborne or airborne GNSS‐R to measure an inland water wind vector and wave heights could contribute to scientific applications focused on understanding nearshore ecosystems, monitoring climate change effects on inland waters, sediment resuspension, biomass production, fish habitat, and others. This paper presents a novel approach to potentially retrieve wind vector and wave heights over inland waters using GNSS‐R and discusses the issues with performing such retrievals using simulation and very few available raw signals recorded from CYGNSS satellites., Key Points Global Navigation Satellite Systems (GNSS) signals reflected from inland waters exhibit coherent scattering properties that make them highly sensitive to water surface roughnessWind‐induced roughness will vary across a water body, with a strong dependence on wind speed, wind direction, and the water depthDiscuss potentials of a novel model‐based approach for retrieval a of wind vector and surface wave heights over lakes using CYGNSS data

Published

2021

33. Volcanic Vortex Rings: Axial Dynamics, Acoustic Features, and Their Link to Vent Diameter and Supersonic Jet Flow

Author

Tullio Ricci, J. J. Peña Fernández, Jörn Sesterhenn, Jacopo Taddeucci, Ulrich Kueppers, Valeria Cigala, E. Del Bello, Stefano Panunzi, and Piergiorgio Scarlato

Subjects

Space Geodetic Surveys, 010504 meteorology & atmospheric sciences, Biogeosciences, 01 natural sciences, Volcanic Effects, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Supersonic speed, Disaster Risk Analysis and Assessment, Climate and Interannual Variability, Remote Sensing and Disasters, Acoustic wave, Mechanics, Strombolian eruption, Vortex ring, Climate Impact, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Acoustic signature, jet noise, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, vent diameter, Volcanology, Jet noise, Hydrological Cycles and Budgets, Physics::Geophysics, Decadal Ocean Variability, Land/Atmosphere Interactions, Research Letter, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Surface Waves and Tides, Eruption Mechanisms and Flow Emplacement, Atmospheric Composition and Structure, Volcano Monitoring, 010305 fluids & plasmas, Remote Sensing, Instruments and Techniques, Seismology, Climatology, Jet (fluid), Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, symbols, Cryosphere, Impacts of Global Change, Geology, Oceanography: Physical, Risk, Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, symbols.namesake, Paleoceanography, 0103 physical sciences, Climate Dynamics, Remote Sensing of Volcanoes, Stromboli, 0105 earth and related environmental sciences, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Strombolian, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Mach number, Ocean influence of Earth rotation, 13. Climate action, vortex ring, Volcano/Climate Interactions, General Earth and Planetary Sciences, Hydrology, Sea Level: Variations and Mean

Abstract

By injecting a mixture of gas and pyroclasts into the atmosphere, explosive volcanic eruptions frequently generate vortex rings, which are toroidal vortices formed by the jet's initial momentum. Here, we report high‐speed imaging and acoustic measurements of vortex rings sourcing from gas‐rich eruptive jets at Stromboli volcano (Italy). Volcanic vortex rings (VVRs) form at the vent together with an initial compression acoustic wave, VVRs maximum rise velocity being directly proportional to the amplitude and inversely proportional to the duration of the compression wave. The axial rise and acoustic signature of VVRs match well those predicted by recent fluid‐dynamic experiments. This good match allows using the high‐frequency (80–1,000 Hz) component of the jet sound and the time‐dependent rise of VVRs to retrieve two key eruption parameters: the Mach number of the eruptive jets (, Key Points Volcanic vortex rings are formed by gas‐rich, jet‐forming Strombolian‐style explosionsThe explosion acoustic signals bear the signature of the vortex rings and reveal supersonic eruptive jets with Mach number up to 1.5Vent diameter can be estimated from the time‐dependent rise of vortex rings at 0.7 m, in agreement with direct observation from Uncrewed Aerial Vehicle

Published

2021

34. Risky Development: Increasing Exposure to Natural Hazards in the United States

Author

Jennifer K. Balch, Stefan Leyk, Caitlin M. McShane, Virginia Iglesias, Megan E. Cattau, Anna E. Braswell, Joseph McGlinchy, R. Chelsea Nagy, William R. Travis, Matthew W. Rossi, Maxwell B. Joseph, and Michael J. Koontz

Subjects

Space Geodetic Surveys, Vulnerability, Biogeosciences, Volcanic Effects, Critical infrastructure, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Earth and Planetary Sciences (miscellaneous), GE1-350, Disaster Risk Analysis and Assessment, QH540-549.5, General Environmental Science, Climate and Interannual Variability, Remote Sensing and Disasters, Hazard, Climate Impact, Geography, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Natural hazard, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Flood myth, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, exposure, Computational Geophysics, Regional Climate Change, Abrupt/Rapid Climate Change, Informatics, Natural resource economics, vulnerability, Surface Waves and Tides, Atmospheric Composition and Structure, Volcano Monitoring, Remote Sensing, Methods, Seismology, risk, Climatology, Ecology, Nonlinear Geophysics, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Effects of global warming, Climate Dynamics, Remote Sensing of Volcanoes, Baseline (configuration management), Numerical Solutions, Climate Change and Variability, Multihazards, Effusive Volcanism, Land use, Climate Variability, Zillow, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Environmental sciences, Mass Balance, natural hazards, Ocean influence of Earth rotation, Volcano/Climate Interactions, Hydrology, Sea Level: Variations and Mean

Abstract

Losses from natural hazards are escalating dramatically, with more properties and critical infrastructure affected each year. Although the magnitude, intensity, and/or frequency of certain hazards has increased, development contributes to this unsustainable trend, as disasters emerge when natural disturbances meet vulnerable assets and populations. To diagnose development patterns leading to increased exposure in the conterminous United States (CONUS), we identified earthquake, flood, hurricane, tornado, and wildfire hazard hotspots, and overlaid them with land use information from the Historical Settlement Data Compilation data set. Our results show that 57% of structures (homes, schools, hospitals, office buildings, etc.) are located in hazard hotspots, which represent only a third of CONUS area, and ∼1.5 million buildings lie in hotspots for two or more hazards. These critical levels of exposure are the legacy of decades of sustained growth and point to our inability, lack of knowledge, or unwillingness to limit development in hazardous zones. Development in these areas is still growing more rapidly than the baseline rates for the nation, portending larger future losses even if the effects of climate change are not considered., Key Points More than half of the structures in the conterminous United States are exposed to potentially devastating natural hazardsGrowth rates in hazard hotspots exceed the national trendRisk assessments can be improved by considering multiple hazards, mitigation history and fine‐scale data on the built environment

Published

2021

35. Hot spots of glacier mass balance variability in Central Asia

Author

Eric Pohl, Robert McNabb, Etienne Berthier, Martina Barandun, Tomas Saks, Martin Hoelzle, Matthias Huss, Kathrin Naegeli, Laboratoire d'études en Géophysique et océanographie spatiales (LEGOS), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), and Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS)

Subjects

010504 meteorology & atmospheric sciences, Biogeosciences, Volcanic Effects, 01 natural sciences, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Cryosphere, Glacial period, 910 Geography & travel, Water cycle, Disaster Risk Analysis and Assessment, Meltwater, [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, geography.geographical_feature_category, Climate and Interannual Variability, Tien Shan and Pamir, Climate Impact, climate change, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Research Letter, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, 550 Earth sciences & geology, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Glacier, Avalanches, Volcano Seismology, 15. Life on land, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, Physical geography, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Glaciology, Surface Waves and Tides, Atmospheric Composition and Structure, annual glacier mass balance time series, 010502 geochemistry & geophysics, Volcano Monitoring, Remote Sensing, Snow and Ice, Snow, Seismology, Climatology, Radio Oceanography, transient snowlines, Gravity and Isostasy, Marine Geology and Geophysics, hydrological cycle, Physical Modeling, Oceanography: General, Cryospheric Change, cryosphere, transient snowline, Impacts of Global Change, Geology, Oceanography: Physical, Risk, Oceanic, Theoretical Modeling, Climate change, Radio Science, Tsunamis and Storm Surges, Glacier mass balance, Paleoceanography, Climate Dynamics, Numerical Solutions, 0105 earth and related environmental sciences, Climate Change and Variability, geography, Effusive Volcanism, Climate Variability, Ice, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Water resources, Mass Balance, Ocean influence of Earth rotation, 13. Climate action, Volcano/Climate Interactions, General Earth and Planetary Sciences, Hydrology, Sea Level: Variations and Mean

Abstract

The Tien Shan and Pamir mountains host over 28,000 glaciers providing essential water resources for increasing water demand in Central Asia. A disequilibrium between glaciers and climate affects meltwater release to Central Asian rivers, challenging the region's water availability. Previous research has neglected temporal variability. We present glacier mass balance estimates based on transient snowline and geodetic surveys with unprecedented spatiotemporal resolution from 1999/00 to 2017/18. Our results reveal spatiotemporal heterogeneity characterized by two mass balance clusters: (a) positive, low variability, and (b) negative, high variability. This translates into variable glacial meltwater release (≈1–16%) of annual river runoff for two watersheds. Our study reveals more complex climate forcing‐runoff responses and importance of glacial meltwater variability for the region than suggested previously., Key Points Annual glacier mass balance for Central Asia (1999/00–2017/18) is derived by combining transient snowlines, geodetic surveys, and modelingStrong spatiotemporal heterogeneity with contrasting patterns of mass gain and loss are foundHot spots of heterogeneous mass balance variability are associated with highly variable glacier melt water runoff

Published

2021

36. Sources, Occurrence and Characteristics of Fluorescent Biological Aerosol Particles Measured Over the Pristine Southern Ocean

Author

Charlotte M. Robinson, Gang Chen, Sebastian Landwehr, Andrea Baccarini, Martin Schnaiter, Alireza Moallemi, Robin L. Modini, Silvia Henning, Marina Zamanillo, Martin Gysel-Beer, Rafel Simó, Julia Schmale, Swiss Polar Institute, European Commission, Swiss National Science Foundation, Swiss Data Science Center, European Research Council, Australian Research Council, and Agencia Estatal de Investigación (España)

Subjects

010504 meteorology & atmospheric sciences, 02 engineering and technology, Biogeosciences, Volcanic Effects, 01 natural sciences, marine aerosols, Global Change from Geodesy, Oceanography: Biological and Chemical, Volcanic Hazards and Risks, Oceans, Sea Level Change, Earth and Planetary Sciences (miscellaneous), Disaster Risk Analysis and Assessment, Marine Pollution, Climate and Interannual Variability, atmospheric aerosols, bioaerosols, fluorescent aerosols, sea spray aerosols, Southern Ocean, Biota, Fluorescence, Climate Impact, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Indoor bioaerosol, 0207 environmental engineering, Volcanology, Megacities and Urban Environment, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Urban Systems, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Atmosphere, Water Cycles, Modeling, Aerosols and Particles, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Tectonophysics, Space and Planetary Science, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Atmospheric Science, Informatics, Pollution: Urban, Regional and Global, Surface Waves and Tides, Flux, Atmospheric Composition and Structure, 010501 environmental sciences, Atmospheric sciences, Volcano Monitoring, Aerosol and Clouds, ddc:550, 020701 environmental engineering, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Pollution: Urban and Regional, Cryosphere, 0406 Physical Geography and Environmental Geoscience, Impacts of Global Change, Oceanography: Physical, Research Article, Bioaerosol, Risk, Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, Paleoceanography, 0401 Atmospheric Sciences, 0406 Physical Geography and Environmental Geoscience, Evolution of the Earth, Climate Dynamics, 14. Life underwater, Biosphere/Atmosphere Interactions, Numerical Solutions, 0105 earth and related environmental sciences, Evolution of the Atmosphere, Climate Change and Variability, Aerosols, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Sea spray, Mud Volcanism, Aerosol, Air/Sea Constituent Fluxes, Earth sciences, Mass Balance, Ocean influence of Earth rotation, 13. Climate action, Volcano/Climate Interactions, Environmental science, Seawater, 0401 Atmospheric Sciences, Hydrology, Sea Level: Variations and Mean

Abstract

24 pages, 8 figures, supporting information https://doi.org/10.1029/2021JD034811.-- Data Availability Statement: The data set used in this study are available in (1) Antoine et al. (2019) available at https://doi.org/10.5281/zenodo.3406983; (2) Chen et al. (2019) available at https://doi.org/10.5281/zenodo.3559982; (3) Landwehr et al. (2020) available at https://doi.org/10.5281/zenodo.3836439; (4) Landwehr, Thurnherr et al. (2020) available at https://doi.org/10.5194/amt-13-3487-2020; (5) Schmale et al. (2019) available at https://doi.org/10.5281/zenodo.2636709; (6) Tatzelt et al. (2020) available at https://doi.org/10.5281/zenodo.3922147; (7) Thomalla et al., (2020) available at https://doi.org/10.5281/zenodo.3859515; (8) Thurnherr et al. (2020) available at https://doi.org/10.5281/zenodo.4031705; In addition, the fluorescent aerosol and gel–like POM measurements have been uploading as supplementary information supporting this article, In this study, we investigate the occurrence of primary biological aerosol particles (PBAP) over all sectors of the Southern Ocean (SO) based on a 90-day data set collected during the Antarctic Circumnavigation Expedition (ACE) in austral summer 2016–2017. Super-micrometer PBAP (1–16 µm diameter) were measured by a wide band integrated bioaerosol sensor (WIBS-4). Low (3σ) and high (9σ) fluorescence thresholds are used to obtain statistics on fluorescent and hyper-fluorescent PBAP, respectively. Our focus is on data obtained over the pristine ocean, that is, more than 200 km away from land. The results indicate that (hyper-)fluorescent PBAP are correlated to atmospheric variables associated with sea spray aerosol (SSA) particles (wind speed, total super-micrometer aerosol number concentration, chloride and sodium concentrations). This suggests that a main source of PBAP over the SO is SSA. The median percentage contribution of fluorescent and hyper-fluorescent PBAP to super-micrometer SSA was 1.6% and 0.13%, respectively. We demonstrate that the fraction of (hyper-)fluorescent PBAP to total super-micrometer particles positively correlates with concentrations of bacteria and several taxa of pythoplankton measured in seawater, indicating that marine biota concentrations modulate the PBAP source flux. We investigate the fluorescent properties of (hyper-)fluorescent PBAP for several events that occurred near land masses. We find that the fluorescence signal characteristics of particles near land is much more variable than over the pristine ocean. We conclude that the source and concentration of fluorescent PBAP over the open ocean is similar across all sampled sectors of the SO, The authors acknowledge funding for ACE-SPACE, ACE-SORPASSO by the Swiss Polar Institute, and Ferring Pharmaceuticals. ACE-SPACE was carried out with additional support from the European FP7 project BACCHUS (Grant Agreement 49603445). Gang Chen received funding from the cost action of Chemical On-Line cOmpoSition and Source Apportionment of fine aerosol (COLOSSAL, CA16109), a COST related project of the Swiss National Science Foundation, Source apportionment using long-term Aerosol Mass Spectrometry and Aethalometer Measurements (SAMSAM, IZCOZ0_177063). Sebastian Landwehr received funding from the Swiss Data Science Center project c17-02. Andrea Baccarin received funding from the Swiss National Science Foundation (Grant 200021_169090). Julia Schmale holds the Ingvar Kamprad Chair. Martin Gysel-Beer received funding from the ERC under Grant ERC-CoG-615922-BLACARAT. Charlotte Robinson received funding from the Australian Research Council (Grand ARC DP160103387), With the funding support of the ‘Severo Ochoa Centre of Excellence’ accreditation (CEX2019-000928-S), of the Spanish Research Agency (AEI)

Published

2021

37. The Impact of COVID‐19 on CO 2 Emissions in the Los Angeles and Washington DC/Baltimore Metropolitan Areas

Author

James R. Whetstone, Anna Karion, K. L. Mueller, Ray F. Weiss, Steve Prinzivalli, Geoffrey Roest, Charles E. Miller, Jooil Kim, Clayton Fain, K. R. Verhulst, I. Lopez-Coto, Thomas Nehrkorn, Subhomoy Ghosh, Nicholas C. Parazoo, M. E. Mountain, Kevin R. Gurney, Riley M. Duren, Sharon Gourdji, Vineet Yadav, and Ralph F. Keeling

Subjects

Biogeosciences, Volcanic Effects, Global Change from Geodesy, Oceanography: Biological and Chemical, Volcanic Hazards and Risks, Oceans, Sea Level Change, Meteorology & Atmospheric Sciences, Disaster Risk Analysis and Assessment, Marine Pollution, Climate and Interannual Variability, Climate Impact, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Gasoline fuel, Atmospheric Effects, 2019-20 coronavirus outbreak, Volcanology, Megacities and Urban Environment, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, COVID‐19, Research Letter, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Urban Systems, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, carbon dioxide, Aerosols and Particles, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Statistical methods: Descriptive, Computational Geophysics, Regional Climate Change, urban, Natural Hazards, Abrupt/Rapid Climate Change, Atmospheric Science, Informatics, Pollution: Urban, Regional and Global, Surface Waves and Tides, Atmospheric Composition and Structure, Atmospheric sciences, Volcano Monitoring, Computational Methods and Data Processing, Statistical methods: Inferential, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Los Angeles, Oceanography: General, Pollution: Urban and Regional, Statistical Analysis, The COVID‐19 pandemic: linking health, society and environment, Cryosphere, Impacts of Global Change, Oceanography: Physical, Risk, Coronavirus disease 2019 (COVID-19), Oceanic, Theoretical Modeling, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Radio Science, Tsunamis and Storm Surges, inversion, Paleoceanography, Natural gas consumption, Climate Dynamics, Washington DC, Numerical Solutions, Climate Change and Variability, Aerosols, Effusive Volcanism, Climate Variability, COVID-19, General Circulation, Policy Sciences, Climate Impacts, Metropolitan area, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, General Earth and Planetary Sciences, Environmental science, Hydrology, Sea Level: Variations and Mean

Abstract

Responses to COVID‐19 have resulted in unintended reductions of city‐scale carbon dioxide (CO2) emissions. Here, we detect and estimate decreases in CO2 emissions in Los Angeles and Washington DC/Baltimore during March and April 2020. We present three lines of evidence using methods that have increasing model dependency, including an inverse model to estimate relative emissions changes in 2020 compared to 2018 and 2019. The March decrease (25%) in Washington DC/Baltimore is largely supported by a drop in natural gas consumption associated with a warm spring whereas the decrease in April (33%) correlates with changes in gasoline fuel sales. In contrast, only a fraction of the March (17%) and April (34%) reduction in Los Angeles is explained by traffic declines. Methods and measurements used herein highlight the advantages of atmospheric CO2 observations for providing timely insights into rapidly changing emissions patterns that can empower cities to course‐correct CO2 reduction activities efficiently., Key Points Atmospheric CO2 observations can be used to detect the onset of the COVID‐19 response in Los Angeles and Washington DC/BaltimoreRelative reductions in April 2020 associated with COVID‐19 are ∼30% when compared to emissions in 2018 and 2019Decreases in vehicular traffic do not completely explain observed emissions reductions in both Los Angeles and Washington DC/Baltimore

Published

2021

38. Spring Festival and COVID‐19 Lockdown: Disentangling PM Sources in Major Chinese Cities

Author

Congbo Song, Zongbo Shi, Yinchang Feng, Philip K. Hopke, Yufen Zhang, Linlu Hou, Bowen Liu, and Qili Dai

Subjects

010504 meteorology & atmospheric sciences, Air pollution, Biogeosciences, Volcanic Effects, 01 natural sciences, Global Change from Geodesy, Oceanography: Biological and Chemical, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, geography.geographical_feature_category, Marine Pollution, Climate and Interannual Variability, History of Geophysics, Climate Impact, machine learning, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Megacities and Urban Environment, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, COVID‐19, Spring (hydrology), Research Letter, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Urban Systems, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Atmosphere, Water Cycles, Modeling, Aerosols and Particles, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Tectonophysics, Mixed effects, Computational Geophysics, Regional Climate Change, Physical geography, meteorological normalization, Natural Hazards, spring festival, Abrupt/Rapid Climate Change, Atmospheric Science, Informatics, Pollution: Urban, Regional and Global, Surface Waves and Tides, Fireworks, Atmospheric Composition and Structure, 010502 geochemistry & geophysics, medicine.disease_cause, Volcano Monitoring, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, air quality, Oceanography: General, Pollution: Urban and Regional, The COVID‐19 pandemic: linking health, society and environment, Cryosphere, Impacts of Global Change, Oceanography: Physical, Risk, source, Coronavirus disease 2019 (COVID-19), Oceanic, Theoretical Modeling, Atmospheric Sciences, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Evolution of the Earth, Climate Dynamics, medicine, Biosphere/Atmosphere Interactions, China, Air quality index, Numerical Solutions, 0105 earth and related environmental sciences, Evolution of the Atmosphere, Climate Change and Variability, Aerosols, geography, Effusive Volcanism, Climate Variability, Chinese spring, COVID-19, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, General Earth and Planetary Sciences, Environmental science, Hydrology, Sea Level: Variations and Mean

Abstract

Responding to the 2020 COVID‐19 outbreak, China imposed an unprecedented lockdown producing reductions in air pollutant emissions. However, the lockdown driven air pollution changes have not been fully quantified. We applied machine learning to quantify the effects of meteorology on surface air quality data in 31 major Chinese cities. The meteorologically normalized NO2, O3, and PM2.5 concentrations changed by −29.5%, +31.2%, and −7.0%, respectively, after the lockdown began. However, part of this effect was also associated with emission changes due to the Chinese Spring Festival, which led to ∼14.1% decrease in NO2, ∼6.6% increase in O3 and a mixed effect on PM2.5 in the studied cities that largely resulted from festival associated fireworks. After decoupling the weather and Spring Festival effects, changes in air quality attributable to the lockdown were much smaller: −15.4%, +24.6%, and −9.7% for NO2, O3, and PM2.5, respectively., Key Points The Chinese Spring Festival led to a 14.1% decrease in NO2, 6.6% increase in O3 and a mixed effect on PM2.5 across China in 2015–2019The 2020 lockdown resulted in −15.4%, −17.0%, −14.5%, −7.6%, −9.7%, and +24.6% changes for NO2, SO2, CO, PM10, PM2.5, and O3, respectivelyFireworks emissions contributed to haze in many cities such as an additional 29 μg m−3 PM2.5 in Beijing on the first lunar day of 2020

Published

2021

39. Investigating Mesozoic Climate Trends and Sensitivities With a Large Ensemble of Climate Model Simulations

Author

Jan Landwehrs, Michael Wagreich, Stefan Petri, Georg Feulner, and Benjamin Sames

Subjects

Abrupt/Rapid Climate Change, Atmospheric Science, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, Jurassic, Oceanography, Biogeosciences, Volcanic Effects, Volcano Monitoring, Cretaceous, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Seismology, climate modeling, Climatology, Radio Oceanography, Climate and Interannual Variability, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Information Related to Geologic Time, Atmospheric Processes, Cryosphere, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Impacts of Global Change, Atmospheric, Geology, Regional Modeling, Oceanography: Physical, Research Article, Global Climate Models, Risk, Atmospheric Effects, Pangaea, Oceanic, Theoretical Modeling, Volcanology, Supercontinent, Hydrological Cycles and Budgets, Radio Science, Tsunamis and Storm Surges, Decadal Ocean Variability, Land/Atmosphere Interactions, Paleoceanography, Paleoclimatology, Climate Dynamics, paleoclimate, Mesozoic, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Sea level, Solid Earth, Numerical Solutions, Climate Change and Variability, Geological, Effusive Volcanism, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Climate Variability, Water Cycles, Modeling, Paleontology, General Circulation, Policy Sciences, Avalanches, Climate Impacts, Volcano Seismology, Benefit‐cost Analysis, Triassic, Mud Volcanism, Air/Sea Constituent Fluxes, Plate tectonics, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Climate model, Computational Geophysics, Regional Climate Change, Hydrology, Sea Level: Variations and Mean, Natural Hazards

Abstract

The Mesozoic era (∼252 to 66 million years ago) was a key interval in Earth's evolution toward its modern state, witnessing the breakup of the supercontinent Pangaea and significant biotic innovations like the early evolution of mammals. Plate tectonic dynamics drove a fundamental climatic transition from the early Mesozoic supercontinent toward the Late Cretaceous fragmented continental configuration. Here, key aspects of Mesozoic long‐term environmental changes are assessed in a climate model ensemble framework. We analyze so far the most extended ensemble of equilibrium climate states simulated for evolving Mesozoic boundary conditions covering the period from 255 to 60 Ma in 5 Myr timesteps. Global mean temperatures are generally found to be elevated above the present and exhibit a baseline warming trend driven by rising sea levels and increasing solar luminosity. Warm (Triassic and mid‐Cretaceous) and cool (Jurassic and end‐Cretaceous) anomalies result from pCO2 changes indicated by different reconstructions. Seasonal and zonal temperature contrasts as well as continental aridity show an overall decrease from the Late Triassic‐Early Jurassic to the Late Cretaceous. Meridional temperature gradients are reduced at higher global temperatures and less land area in the high latitudes. With systematic sensitivity experiments, the influence of paleogeography, sea level, vegetation patterns, pCO2, solar luminosity, and orbital configuration on these trends is investigated. For example, long‐term seasonality trends are driven by paleogeography, but orbital cycles could have had similar‐scale effects on shorter timescales. Global mean temperatures, continental humidity, and meridional temperature gradients are, however, also strongly affected by pCO2., Key Points We assess global long‐term climate trends through the Mesozoic era with an ensemble of climate model simulationsVarying carbon dioxide levels cause anomalies around an overall warming trend due to changing paleogeography and increasing insolationSeasonal and zonal temperature contrasts as well as aridity decrease with time, while meridional gradients vary with paleogeography

Published

2021

40. Identifying Key Drivers of Wildfires in the Contiguous US Using Machine Learning and Game Theory Interpretation

Author

Yun Qian, Sally S.-C. Wang, L. Ruby Leung, and Yang Zhang

Subjects

Vapour Pressure Deficit, computer.software_genre, Biogeosciences, Volcanic Effects, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Earth and Planetary Sciences (miscellaneous), GE1-350, Disaster Risk Analysis and Assessment, QH540-549.5, Permafrost, Cryosphere, and High‐latitude Processes, General Environmental Science, Interpretability, Climate and Interannual Variability, Contrast (statistics), Grid cell, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Planetary Sciences: Comets and Small Bodies, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Hydrological Cycles and Budgets, Cryobiology, Decadal Ocean Variability, Land/Atmosphere Interactions, Comets, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Atmosphere, Water Cycles, Modeling, wildfire modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Tectonophysics, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Surface Waves and Tides, Permafrost, Atmospheric Composition and Structure, Volcano Monitoring, Machine Learning, Planetary Sciences: Solar System Objects, Seismology, Climatology, Ecology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Asteroids, Oceanography: General, Comets: Dust Tails and Trails, Cryosphere, Game theory, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, Predictor variables, Machine learning, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Evolution of the Earth, Climate Dynamics, Neural Networks, Fuzzy Logic, Machine Learning, Biosphere/Atmosphere Interactions, Numerical Solutions, Evolution of the Atmosphere, Climate Change and Variability, Effusive Volcanism, Fire regime, business.industry, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Environmental sciences, Air/Sea Constituent Fluxes, Wildland Fire Model, Mass Balance, Ocean influence of Earth rotation, Wildfire modeling, Volcano/Climate Interactions, Environmental science, Fire in the Earth System, Artificial intelligence, Other, Hydrology, business, Sea Level: Variations and Mean, computer

Abstract

Understanding the complex interrelationships between wildfire and its environmental and anthropogenic controls is crucial for wildfire modeling and management. Although machine learning (ML) models have yielded significant improvements in wildfire predictions, their limited interpretability has been an obstacle for their use in advancing understanding of wildfires. This study builds an ML model incorporating predictors of local meteorology, land‐surface characteristics, and socioeconomic variables to predict monthly burned area at grid cells of 0.25° × 0.25° resolution over the contiguous United States. Besides these predictors, we construct and include predictors representing the large‐scale circulation patterns conducive to wildfires, which largely improves the temporal correlations in several regions by 14%–44%. The Shapley additive explanation is introduced to quantify the contributions of the predictors to burned area. Results show a key role of longitude and latitude in delineating fire regimes with different temporal patterns of burned area. The model captures the physical relationship between burned area and vapor pressure deficit, relative humidity (RH), and energy release component (ERC), in agreement with the prior findings. Aggregating the contribution of predictor variables of all the grids by region, analyses show that ERC is the major contributor accounting for 14%–27% to large burned areas in the western US. In contrast, there is no leading factor contributing to large burned areas in the eastern US, although large‐scale circulation patterns featuring less active upper‐level ridge‐trough and low RH two months earlier in winter contribute relatively more to large burned areas in spring in the southeastern US., Key Points US fire burned areas are well predicted by a machine learning model and SHAP improves interpretation of the contributing factorsIncluding large‐scale circulation patterns conducive to wildfires as predictors improve prediction of burned areas in several regionsFire‐season fuel dryness and dry winters are important contributors to large burned areas in western and southeastern US, respectively

Published

2021

41. Storm Waves May Be the Source of Some 'Tsunami' Coastal Boulder Deposits

Author

Andrew B. Kennedy, Rónadh Cox, and Frédéric Dias

Subjects

Biogeosciences, 01 natural sciences, Volcanic Effects, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Climate and Interannual Variability, Wave climate, Climate Impact, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Littoral Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, 010506 paleontology, Volcanology, Hydrological Cycles and Budgets, wave runup, Decadal Ocean Variability, Land/Atmosphere Interactions, Research Letter, coastal boulder deposits, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, water waves, Modeling, Storm, Avalanches, Volcano Seismology, Benefit‐cost Analysis, inundation risk, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Storm wave, Surface Waves and Tides, Atmospheric Composition and Structure, 010502 geochemistry & geophysics, Volcano Monitoring, Seismology, Climatology, Radio Oceanography, 4304 Oceanic, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Oceanography, 4564 Tsunamis and storm surges, 4560 Surface waves and tides, Cryosphere, Impacts of Global Change, 3020 Littoral processes, Geology, Oceanography: Physical, Risk, Oceanic, Theoretical Modeling, dimensional analysis, Context (language use), Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, 14. Life underwater, 0105 earth and related environmental sciences, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, 13. Climate action, Volcano/Climate Interactions, General Earth and Planetary Sciences, Hydrology, Sea Level: Variations and Mean

Abstract

Coastal boulder deposits (CBD) provide what are sometimes the only remaining signatures of wave inundation on rocky coastlines; in recent decades, CBD combined with initiation of motion (IoM) analyses have repeatedly been used as primary evidence to infer the existence of ancient tsunamis. However, IoM storm wave heights inferred by these studies have been shown to be highly inaccurate, bringing some inferences into question. This work develops a dimensionless framework to relate CBD properties with storm‐wave hindcasts and measurements, producing data‐driven relations between wave climate and boulder properties. We present an elevation‐density‐size‐inland distance‐wave height analysis for individual storm‐transported boulders which delineates the dynamic space where storm‐wave CBD occur. Testing these new relations against presumed tsunami CBD demonstrates that some fall well within the capabilities of storm events, suggesting that some previous studies might be fruitfully reexamined within the context of this new framework., Key Points Size, elevation, and distance inland in storm‐wave‐generated coastal boulder deposits are all functions of climatological wave heightsClear data ranges exist where storm wave coastal boulder deposits do/do not existSome coastal boulder deposits previously identified as having tsunami origin may have been generated by storm waves

Published

2021

42. Spatial Characteristics of Coronavirus Disease 2019 and Their Possible Relationship With Environmental and Meteorological Factors in Hubei Province, China

Author

Wen Zhou, Xiaochi Huang, Jiejun Huang, Yanbin Yuan, Han Zhou, and Xiaofeng Yang

Subjects

Epidemiology, Geographic Information Systems (GIS), Biogeosciences, Volcanic Effects, spatial autocorrelation, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Socioeconomics, Waste Management and Disposal, Water Science and Technology, Global and Planetary Change, Fourier Analysis, Climate and Interannual Variability, Pollution, Climate Impact, Geography, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Spatial Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, environmental and meteorological factors, Land/Atmosphere Interactions, COVID‐19, TD169-171.8, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Spatial Analysis, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Public Health, Environmental and Occupational Health, Electromagnetics, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Spectral Analysis, Nonlinear Waves, Shock Waves, Solitons, Space Plasma Physics, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, ESDA, Surface Waves and Tides, Atmospheric Composition and Structure, Environmental protection, Volcano Monitoring, Remote Sensing and Electromagnetic Processes, Seismology, Climatology, Ionospheric Propagation, Hubei province, Nonlinear Geophysics, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Shock Waves, The COVID‐19 pandemic: linking health, society and environment, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Coronavirus disease 2019 (COVID-19), Oceanic, Theoretical Modeling, Wavelet Transform, Spatial distribution, Spatial Analysis and Representation, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Solitons and Solitary Waves, Ionosphere, China, GWR, Air quality index, Spatial analysis, Productivity, Environmental quality, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Spatial clustering, Wave Propagation, Hydrology, Sea Level: Variations and Mean

Abstract

As of July 27, 2020, COVID‐19 has caused 640,000 deaths worldwide and has had a major impact on people's productivity and lives. Analyzing the spatial distribution characteristics of COVID‐19 cases and their relationships with meteorological and environmental factors might help enrich our knowledge of virus transmission and formulate reasonable epidemic prevention strategies. Taking the cumulative confirmed cases in Hubei province from January 23, 2020, to April 8, 2020, as an example, this study analyzed the spatial evolution characteristics of confirmed COVID‐19 cases in Hubei province using exploratory spatial data analysis and explored the spatial relationship between the main environmental and meteorological factors and confirmed COVID‐19 cases using a geographically weighted regression (GWR) model. Results show that there was no obvious spatial clustering of confirmed COVID‐19 cases in Hubei province, while the decline and end of the newly confirmed cases revealed relatively obvious negative spatial correlations. Due to the lockdown in Hubei province, the main air quality indexes (e.g., AQI and PM2.5) decreased significantly and environmental quality was better than historical contemporaneous levels. Meanwhile, the results of the GWR model suggest that the impacts of environmental and meteorological factors on the development of COVID‐19 were not significant. These findings indicate that measures such as social distancing and isolation played the primary role in controlling the development of the COVID‐19 epidemic., Key Points The spatiotemporal patterns of COVID‐19 cases in Hubei Province were analyzedAnomalies of environmental and meteorological factors contributed little to COVID‐19 developmentSocial distancing and isolation played a key role in controlling the epidemic

Published

2021

43. Dynamical Variations of the Global COVID-19 Pandemic Based on a SEICR Disease Model: A New Approach of Yi Hua Jie Mu

Author

Qi Hu, Daihai He, Xiaomei Feng, Qianqian Cui, Gang Yin, Zhidong Teng, Jiansen Li, Zengyun Hu, Qiming Zhou, and Xia Wang

Subjects

Epidemiology, Biogeosciences, Volcanic Effects, law.invention, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Waste Management and Disposal, Water Science and Technology, Global and Planetary Change, Climate and Interannual Variability, COVID‐19 pandemic, Pollution, Climate Impact, Geography, Transmission (mechanics), Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Public Health, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, TD169-171.8, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Public Health, Environmental and Occupational Health, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, periodic variation, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, Surface Waves and Tides, Atmospheric Composition and Structure, Environmental protection, Koppen‐Geiger climate classification, Volcano Monitoring, law, Pandemic, Seismology, Climatology, Radio Oceanography, Geohealth, Gravity and Isostasy, Marine Geology and Geophysics, scenario analysis, Physical Modeling, Oceanography: General, The COVID‐19 pandemic: linking health, society and environment, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Temperate climate, Scenario analysis, Southern Hemisphere, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Desert climate, Climate Variability, Northern Hemisphere, General Circulation, Policy Sciences, Climate Impacts, Arid, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Hydrology, Sea Level: Variations and Mean

Abstract

The ongoing coronavirus disease 2019 (COVID‐19) pandemic has caused more than 150 million cases of infection to date and poses a serious threat to global public health. In this study, global COVID‐19 data were used to examine the dynamical variations from the perspectives of immunity and contact of 84 countries across the five climate regions: tropical, arid, temperate, and cold. A new approach named Yi Hua Jie Mu is proposed to obtain the transmission rates based on the COVID‐19 data between the countries with the same climate region over the Northern Hemisphere and Southern Hemisphere. Our results suggest that the COVID‐19 pandemic will persist over a long period of time or enter into regular circulation in multiple periods of 1–2 years. Moreover, based on the simulated results by the COVID‐19 data, it is found that the temperate and cold climate regions have higher infection rates than the tropical and arid climate regions, which indicates that climate may modulate the transmission of COVID‐19. The role of the climate on the COVID‐19 variations should be concluded with more data and more cautions. The non‐pharmaceutical interventions still play the key role in controlling and prevention this global pandemic., Key Points A new approached is proposed to predict the future COVID‐19 variations rather than relying on information on other corona virusesCOVID‐19 pandemic will persist in multiple periods of 1–2 yearsThe temperate and cold climate regions have higher infection rates than the tropical and arid climate regions

Published

2021

44. Modeling the Spatiotemporal Association Between COVID‐19 Transmission and Population Mobility Using Geographically and Temporally Weighted Regression

Author

Yixiang Chen, Chao Wu, Min Chen, Wenjia Shi, and Bo Huang

Subjects

Geographic mobility, Epidemiology, Biogeosciences, Volcanic Effects, law.invention, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Waste Management and Disposal, Water Science and Technology, Global and Planetary Change, education.field_of_study, Climate and Interannual Variability, population movement, Pollution, Climate Impact, Geography, Transmission (mechanics), Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Public Health, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, COVID‐19, TD169-171.8, Geodesy and Gravity, Global Change, Air/Sea Interactions, Association (psychology), education, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Public Health, Environmental and Occupational Health, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, heterogeneity, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, Surface Waves and Tides, Atmospheric Composition and Structure, Environmental protection, Volcano Monitoring, law, Seismology, time, Climatology, Radio Oceanography, Geohealth, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, GIS science, The COVID‐19 pandemic: linking health, society and environment, Cryosphere, Impacts of Global Change, Cartography, Oceanography: Physical, Research Article, Risk, Mainland China, Coronavirus disease 2019 (COVID-19), Oceanic, Theoretical Modeling, Population, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Climate Variability, Geospatial, General Circulation, Policy Sciences, space, Targeted interventions, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Hydrology, Sea Level: Variations and Mean, Unit-weighted regression

Abstract

The ongoing Coronavirus Disease 2019 (COVID‐19) has posed a serious threat to human public health and global economy. Population mobility is an important factor that drives the spread of COVID‐19. This study aimed to quantitatively evaluate the impact of population flow on the spread of COVID‐19 from a spatiotemporal perspective. To this end, a case study was carried out in Hubei Province, which was once the most affected area of COVID‐19 outbreak in Mainland China. The geographically and temporally weighted regression (GTWR) model was applied to model the spatiotemporal association between COVID‐19 epidemic and population mobility. Two patterns of population flows, including the population inflow from Wuhan and intra‐city population movement, were considered to construct explanatory variables. Results indicate that the GTWR model can reveal the spatial–temporal‐varying relationships between COVID‐19 and population mobility. Moreover, the association between COVID‐19 case counts and population movements presented three stages of temporal variation characteristics due to the virus incubation period and implementation of strict lockdown measures. In the spatial dimension, evident geographical disparities were observed across Hubei Province. These findings can provide policymakers useful knowledge about the impact of population movement on the spatio‐temporal transmission of COVID‐19. Thus, targeted interventions, if necessary in certain time periods, can be implemented to restrict population flow in cities with high transmission risk., Key Points To quantitatively evaluate how the effect of population flows on COVID‐19 spread varies over time and space in Hubei Province, ChinaThe association showed three stages of temporal variation characteristics and strong geographical disparities across Hubei ProvinceThe implementation of control measures by restricting population movements can play a key role in mitigating the spread of this epidemic

Published

2021

45. A Comparison of Six Transport Models of the MADE‐1 Experiment Implemented With Different Types of Hydraulic Data

Author

Peter Dietrich, Gedeon Dagan, Sabine Attinger, Aldo Fiori, Vladimir Cvetkovic, Alberto Bellin, Georg Teutsch, Marco Dentz, Alraune Zech, European Research Council, Dentz, Marco [0000-0002-3940-282X], Dentz, Marco, Zech, A., Attinger, S., Bellin, A., Cvetkovic, V., Dagan, G., Dentz, M., Dietrich, P., Fiori, A., Teutsch, G., Environmental hydrogeology, and Hydrogeology

Subjects

Length scale, Biogeosciences, Volcanic Effects, Flow measurement, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, heterogeneous aquifer, Hydraulic Data, Disaster Risk Analysis and Assessment, Water Science and Technology, Mass distribution, Climate and Interannual Variability, Mechanics, Plume, Groundwater Transport, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, contaminant transport, Regional Modeling, Atmospheric Effects, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Mass transfer, geostatistics, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Advection, Water Cycles, Modeling, Stochastic Hydrology, Avalanches, Volcano Seismology, Benefit‐cost Analysis, MADE tracer test, heterogeneous aquifers, model comparison, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Spatial correlation, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, Volcano Monitoring, Groundwater Hydrology, Seismology, Climatology, Transport Models, Radio Oceanography, AMDE tracer test, Sampling (statistics), Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Numerical Solutions, Climate Change and Variability, Effusive Volcanism, Climate Variability, Groundwater Quality, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Environmental science, geostatistic, Hydrology, Sea Level: Variations and Mean

Abstract

Six conceptually different transport models were applied to the macrodispersion experiment (MADE)-1 field tracer experiment as a first major attempt for model comparison. The objective was to show that complex mass distributions in heterogeneous aquifers can be predicted without calibration of transport parameters, solely making use of structural and flow data. The models differ in their conceptualization of the heterogeneous aquifer structure, computational complexity, and use of conductivity data obtained from various observation methods (direct push injection logging, DPIL, grain size analysis, pumping tests and flowmeter). They share the same underlying physical transport process of advection by the velocity field solely. Predictive capability is assessed by comparing results to observed longitudinal mass distributions of the MADE-1 experiment. The decreasing mass recovery of the observed plume is attributed to sampling and no physical process like mass transfer is invoked by the models. Measures like peak location and strength are used in comparing the modeled and measured plume mass distribution. Comparison of models reveals that the predictions of the solute plume agree reasonably well with observations, if the models are underlain by a few parameters of close values: mean velocity, a parameter reflecting log-conductivity variability, and a horizontal length scale related to conductivity spatial correlation. The robustness of the results implies that conservative transport models with appropriate conductivity upscaling strategies of various observation data provide reasonable predictions of plumes longitudinal mass distribution, as long as key features are taken into account., The authors thank Marco Bianchi and Boris Baeumer for their support during the development of the study. A. Fiori and A. Bellin acknowledge funding from the Italian Ministry of Education, University and Research (MIUR) in the frame of the Departments of Excellence Initiative 2018–2022 granted to Dept. of Engineering of Roma Tre University, and to the Dept. of Civil, Environmental and Mechanical Engineering of the University of Trento, respectively. M. Dentz acknowledges funding of the European Research Council (ERC) through the project MHetScale (contract number 617511), and the Spanish Research Agency (AEI) through the project HydroPore (contract number PID2019-106887GB-C31).

Published

2021

46. Role of Atmospheric Indices in Describing Inshore Directional Wave Climate in the United Kingdom and Ireland

Author

Andy Saulter, Gerd Masselink, Guillaume Dodet, Adam A. Scaife, Tim Scott, Bruno Castelle, Robert Jak McCarroll, Nick Dunstone, School of Biological and Marine Sciences, Plymouth University, Environnements et Paléoenvironnements OCéaniques (EPOC), Observatoire aquitain des sciences de l'univers (OASU), Université Sciences et Technologies - Bordeaux 1-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Sciences et Technologies - Bordeaux 1-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS), Laboratoire d'Océanographie Physique et Spatiale (LOPS), Institut de Recherche pour le Développement (IRD)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS), United Kingdom Met Office [Exeter], College of Engineering, Mathematics and Physical Sciences [Exeter] (EMPS), University of Exeter, Université Sciences et Technologies - Bordeaux 1 (UB)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Sciences et Technologies - Bordeaux 1 (UB)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-École Pratique des Hautes Études (EPHE), Institut de Recherche pour le Développement (IRD)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS), and ANR-17-CE01-0014,SONO,Marier les objectifs de défense côtière avec ceux de la protection du milieu naturel grâce aux dunes sableuses(2017)

Subjects

010504 meteorology & atmospheric sciences, Earthquake Source Observations, Biogeosciences, 01 natural sciences, Volcanic Effects, Global Change from Geodesy, Ionospheric Physics, Volcanic Hazards and Risks, Oceans, Sea Level Change, Earth and Planetary Sciences (miscellaneous), GE1-350, Disaster Risk Analysis and Assessment, Earthquake Interaction, Forecasting, and Prediction, QH540-549.5, General Environmental Science, Gravity Methods, climate indices, Climate and Interannual Variability, Wave climate, Seismic Cycle Related Deformations, Tectonic Deformation, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Time Variable Gravity, Earth System Modeling, Atmospheric Processes, Seismicity and Tectonics, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Probabilistic Forecasting, Regional Modeling, Atmospheric Effects, [SDE.MCG]Environmental Sciences/Global Changes, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Earthquake Dynamics, Magnetospheric Physics, Geodesy and Gravity, Global Change, wave direction, Air/Sea Interactions, [SDU.ENVI]Sciences of the Universe [physics]/Continental interfaces, environment, Numerical Modeling, Solid Earth, [SDU.STU.OC]Sciences of the Universe [physics]/Earth Sciences/Oceanography, Gravity anomalies and Earth structure, Geological, inshore wave climate, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, seasonal forecasting, Computational Geophysics, Regional Climate Change, Subduction Zones, Transient Deformation, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, 010502 geochemistry & geophysics, Volcano Monitoring, long term prediction, Range (statistics), Seismology, Climatology, Exploration Geophysics, Ecology, Ocean Predictability and Prediction, Radio Oceanography, Coastal Processes, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Regression, Oceanography: General, Policy, Estimation and Forecasting, Space Weather, Cryosphere, Impacts of Global Change, Oceanography: Physical, Research Article, coastal evolution, Risk, Oceanic, Theoretical Modeling, Satellite Geodesy: Results, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Ionosphere, Long-term prediction, Monitoring, Forecasting, Prediction, 0105 earth and related environmental sciences, Wave power, Numerical Solutions, Climate Change and Variability, Continental Crust, Effusive Volcanism, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Environmental sciences, Mass Balance, Interferometry, Ocean influence of Earth rotation, 13. Climate action, Seasonal forecasting, Volcano/Climate Interactions, Environmental science, Hydrology, Prediction, Sea Level: Variations and Mean, Forecasting

Abstract

Improved understanding of how our coasts will evolve over a range of time scales (years‐decades) is critical for effective and sustainable management of coastal infrastructure. A robust knowledge of the spatial, directional and temporal variability of the inshore wave climate is required to predict future coastal evolution and hence vulnerability. However, the variability of the inshore directional wave climate has received little attention, and an improved understanding could drive development of skillful seasonal or decadal forecasts of coastal response. We examine inshore wave climate at 63 locations throughout the United Kingdom and Ireland (1980–2017) and show that 73% are directionally bimodal. We find that winter‐averaged expressions of six leading atmospheric indices are strongly correlated (r = 0.60–0.87) with both total and directional winter wave power (peak spectral wave direction) at all studied sites. Regional inshore wave climate classification through hierarchical cluster analysis and stepwise multi‐linear regression of directional wave correlations with atmospheric indices defined four spatially coherent regions. We show that combinations of indices have significant skill in predicting directional wave climates (R 2 = 0.45–0.8; p, Key Points Over 70% of inshore wave climates analyzed throughout the United Kingdom and Ireland were directionally bimodalCombinations of winter atmospheric indices NAO, WEPA, SCAND, and EA are significantly correlated with directional wave climate in all regionsRegression models using multiple winter atmospheric indices enable skillful reconstructions of directional wave climate in all regions

Published

2021

47. The Climate Response to Emissions Reductions Due to COVID‐19: Initial Results From CovidMIP

Author

John C. Fyfe, Jonathan E. Hickman, Tilo Ziehn, Joeri Rogelj, Katherine Calvin, Tatiana Ilyina, Lili Ren, Nathan P. Gillett, Ragnhild Bieltvedt Skeie, Klaus Wyser, Yang Yang, Yangming Tang, Claudia Timmreck, Chloe Mackallah, Chris D. Jones, Tsuyoshi Koshiro, Shuting Yang, Naga Oshima, Manabu Abe, Slava Kharin, Jeremy Walton, Robin Lamboll, Piers M. Forster, Stephanie Fiedler, Kostas Tsigaridis, Wolfgang A. Müller, Hailong Wang, Mingxuan Wu, Maxwell Kelley, Rumi Ohgaito, Jerry Tjiputra, Twan van Noije, José Antonio Parodi, Christophe Cassou, Michael Botzet, Thomas Reerink, Hongmei Li, Jason N. S. Cole, Anastasia Romanou, S. T. Rumbold, Roland Séférian, Paul Nolan, Paolo Davini, Martin Dix, Makoto Deushi, Etienne Tourigny, Michio Kawamiya, Pierre Nabat, Dirk Jan Leo Oliviè, Met Office Hadley Centre for Climate Change (MOHC), United Kingdom Met Office [Exeter], and Barcelona Supercomputing Center

Subjects

earth system model, 010504 meteorology & atmospheric sciences, Biogeosciences, 01 natural sciences, Klimatforskning, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Center (algebra and category theory), Disaster Risk Analysis and Assessment, media_common, Climate and Interannual Variability, Atmospheric aerosols, Climate Impact, Greenhouse gases, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Publishing, Atmospheric Processes, climate perturbation, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Research center, Research program, Climate Research, [SDE.MCG]Environmental Sciences/Global Changes, Volcanology, Library science, aerosol optical depth, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Political science, Research Letter, media_common.cataloged_instance, Geodesy and Gravity, Global Change, European union, Air/Sea Interactions, Numerical Modeling, Solid Earth, CMIP6, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Atmosphere, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Tectonophysics, Computational Geophysics, Regional Climate Change, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Climate, Surface Waves and Tides, COVID‐19 emissions reductions, Atmospheric Composition and Structure, 010502 geochemistry & geophysics, COVID-19 (Malaltia), Volcano Monitoring, COVID-19 (Disease), CovidMIP, Climate perturbation, Seismology, Climatology, Enginyeria agroalimentària::Ciències de la terra i de la vida::Climatologia i meteorologia [Àrees temàtiques de la UPC], Radio Oceanography, Aire -- Contaminació, COVID-19 emissions reductions, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Cryosphere, Impacts of Global Change, Oceanography: Physical, Risk, Oceanic, Theoretical Modeling, Eearth system model, Aerosol optical depth, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Evolution of the Earth, Climate Dynamics, Earth systems data and models, Biosphere/Atmosphere Interactions, Numerical Solutions, 0105 earth and related environmental sciences, Evolution of the Atmosphere, Climate Change and Variability, Aerosols, Effusive Volcanism, business.industry, Climate Variability, COVID-19, Environmental restoration, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, 13. Climate action, Volcano/Climate Interactions, Sustainability, General Earth and Planetary Sciences, Climate model, Hydrology, Sea Level: Variations and Mean, business

Abstract

Many nations responded to the corona virus disease‐2019 (COVID‐19) pandemic by restricting travel and other activities during 2020, resulting in temporarily reduced emissions of CO2, other greenhouse gases and ozone and aerosol precursors. We present the initial results from a coordinated Intercomparison, CovidMIP, of Earth system model simulations which assess the impact on climate of these emissions reductions. 12 models performed multiple initial‐condition ensembles to produce over 300 simulations spanning both initial condition and model structural uncertainty. We find model consensus on reduced aerosol amounts (particularly over southern and eastern Asia) and associated increases in surface shortwave radiation levels. However, any impact on near‐surface temperature or rainfall during 2020–2024 is extremely small and is not detectable in this initial analysis. Regional analyses on a finer scale, and closer attention to extremes (especially linked to changes in atmospheric composition and air quality) are required to test the impact of COVID‐19‐related emission reductions on near‐term climate., Key Points Lockdown restrictions during COVID‐19 have reduced emissions of aerosols and greenhouse gases12 CMIP6 Earth system models have performed coordinated experiments to assess the impact of this on climateAerosol amounts are reduced over southern and eastern Asia but there is no detectable change in annually averaged temperature or precipitation

Published

2021

48. How Equivalent Are Equivalent Porous Media?

Author

Hossein Salari-Rad, Ahmad Zareidarmiyan, Roman Y. Makhnenko, Víctor Vilarrasa, Francesco Parisio, European Research Council, Ministerio de Ciencia e Innovación (España), Vilarrasa, Víctor, and Vilarrasa, Víctor [0000-0003-1169-4469]

Subjects

Induced seismicity, Thermal effect, 010504 meteorology & atmospheric sciences, Biogeosciences, Volcanic Effects, 01 natural sciences, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Climate and Interannual Variability, Mechanics, Climate Impact, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Fluid injection, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Hydrological Cycles and Budgets, Permeability, Decadal Ocean Variability, Land/Atmosphere Interactions, Research Letter, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Distribution (mathematics), Computational Geophysics, Regional Climate Change, Porous medium, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Surface Waves and Tides, Geomechanics, Atmospheric Composition and Structure, 010502 geochemistry & geophysics, Volcano Monitoring, Fracture and Flow, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Geoenergies, Oceanography: General, Permeability (earth sciences), Permeability and Porosity, Cryosphere, Impacts of Global Change, Geology, Oceanography: Physical, Risk, Oceanic, Theoretical Modeling, Deformation (meteorology), Radio Science, Tsunamis and Storm Surges, Pore water pressure, Paleoceanography, Climate Dynamics, Numerical Approximations and Analysis, Physical Properties of Rocks, Numerical Solutions, 0105 earth and related environmental sciences, Climate Change and Variability, Coupling, Effusive Volcanism, Climate Variability, Ocean Data Assimilation and Reanalysis, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, General Earth and Planetary Sciences, Hydrology, Sea Level: Variations and Mean, Fractures

Abstract

Geoenergy and geoengineering applications usually involve fluid injection into and production from fractured media. Accounting for fractures is important because of the strong poromechanical coupling that ties pore pressure changes and deformation. A possible approach to the problem uses equivalent porous media to reduce the computational cost and model complexity instead of explicitly including fractures in the models. We investigate the validity of this simplification by comparing these two approaches. Simulation results show that pore pressure distribution significantly differs between the two approaches even when both are calibrated to predict identical values at the injection and production wells. Additionally, changes in fracture stability are not well captured with the equivalent porous medium. We conclude that explicitly accounting for fractures in numerical models may be necessary under some circumstances to perform reliable coupled thermohydromechanical simulations, which could be used in conjunction with other tools for induced seismicity forecasting., A.Z. acknowledges the financial support received from the “Iran's Ministry of Science, Research and Technology” (PhD students' sabbatical grants) for visiting IDAEA‐CSIC. The contribution of F.P. is funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)—project number PA 3451/1‐1. R.M. is thankful for the support from US DOE through Carbon SAFE Macon County Project DE‐FE0029381. V.V. acknowledges funding from the Spanish National Research Council (CSIC) through the Intramural project 201730I100 and from the European Research Council (ERC) under the European Union's Horizon 2020 Research and Innovation Program through the Starting Grant GEoREST (www.georest.eu) (Grant agreement No. 801809). IDAEA‐CSIC is a Center of Excellence Severo Ochoa (Spanish Ministry of Science and Innovation, Project CEX2018‐000794‐S). The authors declare no conflict of interest.

Published

2021

49. Comparative Study on Temperature Response of Hydropower Development in the Dry-Hot Valley

Author

Y. Xin, Xian Zhang, Yang Huang, Xiao Wang, M. Qu, Wei Zhang, Dongchuan Wang, and Z. J. Cao

Subjects

Epidemiology, Biogeosciences, Volcanic Effects, Global Change from Geodesy, Reservoir effect, Volcanic Hazards and Risks, Oceans, Sea Level Change, relative temperature, Disaster Risk Analysis and Assessment, Waste Management and Disposal, comparative study, Water Science and Technology, Global and Planetary Change, Downstream Region, Climate and Interannual Variability, Pollution, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Atmospheric, Regional Modeling, Atmospheric Effects, Volcanology, Management, Monitoring, Policy and Law, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Downstream (manufacturing), TD169-171.8, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Public Health, Environmental and Occupational Health, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Computational Geophysics, Regional Climate Change, downstream river temperature change, Natural Hazards, dry‐hot valley, Abrupt/Rapid Climate Change, Informatics, Health, Toxicology and Mutagenesis, Surface Waves and Tides, Atmospheric Composition and Structure, Environmental protection, Volcano Monitoring, reservoir effect change intensity, Dry season, Hydropower, Seismology, Climatology, Radio Oceanography, Gravity and Isostasy, Marine Geology and Geophysics, Hydroclimatology, Physical Modeling, Oceanography: General, Cryosphere, Temperature response, Impacts of Global Change, Oceanography: Physical, Research Article, Wet season, Risk, Oceanic, Theoretical Modeling, Radio Science, Tsunamis and Storm Surges, Paleoceanography, Climate Dynamics, Numerical Solutions, Hydrology, Climate Change and Variability, Effusive Volcanism, business.industry, Climate Variability, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, Environmental science, business, Sea Level: Variations and Mean, Intensity (heat transfer), Dams

Abstract

Due to the specific hydrothermal conditions of dry‐hot valleys, temperature changes caused by the development of large‐scale hydropower projects may be more extreme than they are in other regions. In this study, we analyzed these temperature changes at four hydropower stations in both dry‐hot and non‐dry‐hot valleys. Based on the calculated relative temperatures of the downstream river and the areas surrounding the reservoirs, we employed two indices to quantify the influence of the reservoirs on the temperatures of these two regions: the downstream river temperature change and the reservoir effect change intensity. Our results are as follows: (a) In the downstream rivers, the temperature regulation effect was more pronounced in the wet season; in the regions surrounding the reservoirs, the temperature regulation effect was more pronounced in the dry season. (b) The downstream river temperature in both the dry‐hot and wet‐hot valleys exhibited noticeable warming in both the wet and dry seasons, while the cold‐dry valley was characterized by cooling in the dry season and warming in the wet season. With the exception of the Liyuan station (where the influence of the reservoir on the downstream temperatures only extended to a distance of 9 km from the dam) during the dry season, the existence of the hydropower stations affected the temperatures of the entire downstream region. (c) For the areas surrounding the reservoir, the presence of a hydropower station mainly caused the temperatures in the dry‐hot valleys to rise and the temperatures in the non‐dry‐hot valleys to decrease., Key Points The difference of surface temperature affected by reservoirs was compared in dry‐hot and non‐dry‐hot valleysTo facilitate comparison of the different downstream river temperature changes, downstream river temperature change index was establishedThe reservoir effect change intensity was established to explore how reservoirs regulate the surface temperature in the surrounding areas

Published

2021

50. Single Particle Multipole Expansions From Micromagnetic Tomography

Author

Cortés-Ortuño, David, Fabian, Karl, de Groot, Lennart V., Paleomagnetism, and Paleomagnetism

Subjects

010504 meteorology & atmospheric sciences, Magnetism, Physics::Medical Physics, rock magnetism, Biogeosciences, Volcanic Effects, 01 natural sciences, Physics - Geophysics, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Disaster Risk Analysis and Assessment, Climate and Interannual Variability, Computational Physics (physics.comp-ph), Climate Impact, Geophysics, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Earth System Modeling, Atmospheric Processes, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Mathematical Geophysics, Atmospheric, Physics - Computational Physics, micromagnetic tomography, Regional Modeling, Atmospheric Effects, multipole, Volcanology, Hydrological Cycles and Budgets, Decadal Ocean Variability, Land/Atmosphere Interactions, Inverse Theory, Geochemistry and Petrology, Geodesy and Gravity, Global Change, Magnetic and Electrical Properties, Air/Sea Interactions, Numerical Modeling, Solid Earth, Geological, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Water Cycles, Modeling, Avalanches, Volcano Seismology, Benefit‐cost Analysis, Dipole, magnetism, Computational Geophysics, Regional Climate Change, Multipole expansion, Natural Hazards, Abrupt/Rapid Climate Change, Informatics, Surface Waves and Tides, Atmospheric Composition and Structure, 010502 geochemistry & geophysics, Volcano Monitoring, Geomagnetism and Paleomagnetism, Seismology, Climatology, Exploration Geophysics, Radio Oceanography, paleomagnetism, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Condensed Matter - Other Condensed Matter, Oceanography: General, Cryosphere, Impacts of Global Change, Geology, Oceanography: Physical, Research Article, Risk, Oceanic, Theoretical Modeling, FOS: Physical sciences, Radio Science, Tsunamis and Storm Surges, Magnetization, Paleoceanography, Climate Dynamics, Numerical Approximations and Analysis, Physical Properties of Rocks, Numerical Solutions, 0105 earth and related environmental sciences, Climate Change and Variability, Effusive Volcanism, Climate Variability, Ocean Data Assimilation and Reanalysis, General Circulation, Policy Sciences, Climate Impacts, Mud Volcanism, Geophysics (physics.geo-ph), Computational physics, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Remanence, Volcano/Climate Interactions, Magnetic and Electrical Methods, Particle, Magnetic nanoparticles, Rock and Mineral Magnetism, Magnetic potential, Hydrology, Sea Level: Variations and Mean, Other Condensed Matter (cond-mat.other)

Abstract

Micromagnetic tomography aims at reconstructing large numbers of individual magnetizations of magnetic particles from combining high‐resolution magnetic scanning techniques with micro X‐ray computed tomography (microCT). Previous work demonstrated that dipole moments can be robustly inferred, and mathematical analysis showed that the potential field of each particle is uniquely determined. Here, we describe a mathematical procedure to recover higher orders of the magnetic potential of the individual magnetic particles in terms of their spherical harmonic expansions (SHE). We test this approach on data from scanning superconducting quantum interference device microscopy and microCT of a reference sample. For particles with high signal‐to‐noise ratio of the magnetic scan we demonstrate that SHE up to order n = 3 can be robustly recovered. This additional level of detail restricts the possible internal magnetization structures of the particles and provides valuable rock magnetic information with respect to their stability and reliability as paleomagnetic remanence carriers. Micromagnetic tomography therefore enables a new approach for detailed rock magnetic studies on large ensembles of individual particles., Key Points Micromagnetic Tomography uniquely recovers higher‐order multipole terms for several individual grains in a sampleHigher order multipole moments are an expression of the internal domain structure of magnetic grainsUltimately, this enables to select individual grains for rock‐ and paleomagnetic studies based on domain configuration

Published

2021