Your search keyword '"Cassano, John"' showing total 268 results

251. Clouds and Radiation Processes in Regional Climate Models Evaluated Using Observations Over the Ice‐free Arctic Ocean

Author

Inoue, Jun, Sato, Kazutoshi, Rinke, Annette, Cassano, John J., Fettweis, Xavier, Heinemann, Günther, Matthes, Heidrun, Orr, Andrew, Phillips, Tony, Seefeldt, Mark, Solomon, Amy, and Webster, Stuart

Abstract

The presence of clouds in the Arctic regulates the surface energy budget (SEB) over the sea‐ice surface and the ice‐free ocean. Following several previous field campaigns, the cloud‐radiation relationship, including cloud vertical structure and phase, has been elucidated; however, modeling of this relationship has matured slowly. In recognition of the recent decline in the Arctic sea‐ice extent, representation of the cloud system in numerical models should consider the effects of areas covered by sea ice and ice‐free areas. Using an in situ stationary meteorological observation data set obtained over the ice‐free Arctic Ocean by the Japanese Research Vessel Mirai(September 2014), coordinated evaluation of six regional climate models (RCMs) with nine model runs was performed by focusing on clouds and the SEB. The most remarkable findings were as follows: (1) reduced occurrence of unstable stratification with low‐level cloud water in all models in comparison to the observations, (2) significant differences in cloud water representations between single‐ and double‐moment cloud schemes, (3) extensive differences in partitioning of hydrometeors including solid/liquid precipitation, and (4) pronounced lower‐tropospheric air temperature biases. These issues are considered as the main sources of SEB uncertainty over ice‐free areas of the Arctic Ocean. The results from a coupled RCM imply that the SEB is constrained by both the atmosphere and the ocean (and sea ice) with considerable feedback. Coordinated improvement of both stand‐alone atmospheric and coupled RCMs would promote a more comprehensive and improved understanding of the Arctic air‐ice‐sea coupled system. Discrepancies remain in surface energy budget (SEB) and cloud properties despite constrained boundary conditionsModels underestimate occurrence of unstable stratification with low‐level water cloudsBiases in hydrometeor partitioning essentially contribute to limited skill in SEB simulation Discrepancies remain in surface energy budget (SEB) and cloud properties despite constrained boundary conditions Models underestimate occurrence of unstable stratification with low‐level water clouds Biases in hydrometeor partitioning essentially contribute to limited skill in SEB simulation

Published

2021

252. Observations of Arctic Atmospheric Boundary Layer with Small Unmanned Aerial Vehicles for MOSAiC

Author

Jozef, Gina, de Boer, Gijs, CAssano, John, Lawrence, Dale, Argrow, Brian, Hamilton, Jonathan, Calmer, Radiance, Borenstein, Steven, Doddi, Abhiram, Schmale, Julia, and Preusser, Andreas

253. Advancing Unmanned Aerial Capabilities for Atmospheric Research.

Author

de Boer, Gijs, Argrow, Brian, Cassano, John, Cione, Joseph, Frew, Eric, Lawrence, Dale, Wick, Gary, and Wolff, Cory

Subjects

*EARTH (Planet), *CLIMATOLOGY, *FLOODS, *NUMERICAL analysis, *STORMS

Abstract

The article reports that the policy development for a stable society need the understanding of Earth system, with weather and climate patterns. It mentions that in the U.S. recent storms, flooding, and wildfires reinforce the requirement of understanding the earth. It focuses on the performance of numerical models in the scales. It mentions that the atmosphere, including boundary layer temperature and turbulent structure and clouds has been considered in the analysis.

Published

2019

254. The Thermodynamic Structure of Arctic Coastal Fog Occurring During the Melt Season over East Greenland.

Author

Gilson, Gaëlle F., Jiskoot, Hester, Cassano, John J., Gultepe, Ismail, and James, Timothy D.

Subjects

*THERMODYNAMICS, *FOG, *RADIOSONDE observations of the boundary layer, *TEMPERATURE inversions, *MICROWAVE radiometers

Abstract

An automated method to classify Arctic fog into distinct thermodynamic profiles using historic in-situ surface and upper-air observations is presented. This classification is applied to low-resolution Integrated Global Radiosonde Archive (IGRA) soundings and high-resolution Arctic Summer Cloud Ocean Study (ASCOS) soundings in low- and high-Arctic coastal and pack-ice environments. Results allow investigation of fog macrophysical properties and processes in coastal East Greenland during melt seasons 1980-2012. Integrated with fog observations from three synoptic weather stations, 422 IGRA soundings are classified into six fog thermodynamic types based on surface saturation ratio, type of temperature inversion, fog-top height relative to inversion-base height and stability using the virtual potential temperature gradient. Between 65-80% of fog observations occur with a low-level inversion, and statically neutral or unstable surface layers occur frequently. Thermodynamic classification is sensitive to the assigned dew-point depression threshold, but categorization is robust. Despite differences in the vertical resolution of radiosonde observations, IGRA and ASCOS soundings yield the same six fog classes, with fog-class distribution varying with latitude and environmental conditions. High-Arctic fog frequently resides within an elevated inversion layer, whereas low-Arctic fog is more often restricted to the mixed layer. Using supplementary time-lapse images, ASCOS microwave radiometer retrievals and airmass back-trajectories, we hypothesize that the thermodynamic classes represent different stages of advection fog formation, development, and dissipation, including stratus-base lowering and fog lifting. This automated extraction of thermodynamic boundary-layer and inversion structure can be applied to radiosonde observations worldwide to better evaluate fog conditions that affect transportation and lead to improvements in numerical models. [ABSTRACT FROM AUTHOR]

Published

2018

255. Evaluation of the AMPS Boundary Layer Simulations on the Ross Ice Shelf, Antarctica, with Unmanned Aircraft Observations.

Author

Wille, Jonathan D., Bromwich, David H., Cassano, John J., Nigro, Melissa A., Mateling, Marian E., and Lazzara, Matthew A.

Subjects

*ATMOSPHERIC boundary layer, *DRONE aircraft, *MOISTURE, *WIND speed, *CLOUDINESS

Abstract

Accurately predicting moisture and stability in the Antarctic planetary boundary layer (PBL) is essential for low-cloud forecasts, especially when Antarctic forecasters often use relative humidity as a proxy for cloud cover. These forecasters typically rely on the Antarctic Mesoscale Prediction System (AMPS) Polar Weather Research and Forecasting (Polar WRF) Model for high-resolution forecasts. To complement the PBL observations from the 30-m Alexander Tall Tower! (ATT) on the Ross Ice Shelf as discussed in a recent paper by Wille and coworkers, a field campaign was conducted at the ATT site from 13 to 26 January 2014 using Small Unmanned Meteorological Observer (SUMO) aerial systems to collect PBL data. The 3-km-resolution AMPS forecast output is combined with the global European Centre for Medium-Range Weather Forecasts interim reanalysis (ERAI), SUMO flights, and ATT data to describe atmospheric conditions on the Ross Ice Shelf. The SUMO comparison showed that AMPS had an average 2-3 m s−1 high wind speed bias from the near surface to 600 m, which led to excessive mechanical mixing and reduced stability in the PBL. As discussed in previous Polar WRF studies, the Mellor-Yamada-Janjić PBL scheme is likely responsible for the high wind speed bias. The SUMO comparison also showed a near-surface 10-15-percentage-point dry relative humidity bias in AMPS that increased to a 25-30-percentage-point deficit from 200 to 400 m above the surface. A large dry bias at these critical heights for aircraft operations implies poor AMPS low-cloud forecasts. The ERAI showed that the katabatic flow from the Transantarctic Mountains is unrealistically dry in AMPS. [ABSTRACT FROM AUTHOR]

Published

2017

256. Sea Ice Loss and Arctic Cyclone Activity from 1979 to 2014.

Author

Koyama, Tomoko, Stroeve, Julienne, Cassano, John, and Crawford, Alex

Subjects

*SEA ice, *CYCLONES, *ENVIRONMENTAL impact analysis, *ATMOSPHERIC temperature, *MOISTURE

Abstract

Extensive summer sea ice loss has occurred within the Beaufort, Chukchi, East Siberian, and Laptev Seas over the last decade. Associated anomalies in sensible and latent heat fluxes in autumn have increased Arctic atmospheric precipitable water and air temperatures, with the potential to impact autumn and winter cyclone activity. To examine if a connection exists between recent Arctic sea ice loss and cyclone activity, several cyclone metrics from 60° to 90°N are analyzed. Results show that following years with less September sea ice, there is a subsequent increase in moisture availability, regional baroclinicity, and changes in vertical stability that favor cyclogenesis. However, tracking of individual cyclones indicates no coherent increase in cyclone frequency or intensity associated with sea ice loss. Furthermore, no robust northward progression of extreme cyclones is observed. [ABSTRACT FROM AUTHOR]

Published

2017

257. Antarctic Weather Forecasting Workshop.

Author

Bromwich, David H. and Cassano, John J.

Subjects

*WEATHER forecasting, *ADULT education workshops

Abstract

Highlights the Antarctic Weather Forecasting Workshop (AWFW) held at Byrd Polar Research Center in Ohio State University in Ohio. Topics discussed in the workshop; State of operational weather forecasting in the Antarctic; Recommendations from the workshop.

Published

2001

258. The 16th Workshop on Antarctic Meteorology and Climate and 6th Year of Polar Prediction in the Southern Hemisphere Meeting.

Author

Bromwich, David H., Lazzara, Matthew A., Cayette, Arthur M., Powers, Jordan G., Werner, Kirstin, Cassano, John J., Colwell, Steven R., Carpentier, Scott, and Zou, Xun

Subjects

*ATMOSPHERIC radiation measurement, *METEOROLOGICAL services, *METEOROLOGICAL research, *ATMOSPHERIC physics, *SEA ice, *SEAWATER salinity, ANTARCTIC climate

Published

2022

259. Arctic sea ice anomalies during the MOSAiC winter 2019/20.

Author

Dethloff, Klaus, Maslowski, Wieslaw, Hendricks, Stefan, Lee, Younjoo J., Goessling, Helge F., Krumpen, Thomas, Haas, Christian, Handorf, Dörthe, Ricker, Robert, Bessonov, Vladimir, Cassano, John J., Kinney, Jaclyn Clement, Osinski, Robert, Rex, Markus, Rinke, Annette, Sokolova, Julia, and Sommerfeld, Anja

Subjects

*ICE floes, *SEA ice, *ARCTIC oscillation, *ARCTIC climate, *WIND pressure, *EDDY flux

Abstract

During the winter of 2019/2020, as the Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) project started its work, the Arctic Oscillation (AO) experienced some of its largest shifts, ranging from a highly negative index in November 2019 to an extremely positive index during January–February–March (JFM) 2020. The permanent positive AO phase for the 3 months of JFM 2020 was accompanied by a prevailing positive phase of the Arctic Dipole (AD) pattern. Here we analyze the sea ice thickness (SIT) distribution based on CryoSat-2/SMOS satellite-derived data augmented with results from the hindcast simulation by the fully coupled Regional Arctic System Model (RASM) from November 2019 through March 2020. A notable result of the positive AO phase during JFM 2020 was large SIT anomalies of up to 1.3 m that emerged in the Barents Sea (BS), along the northeastern Canadian coast and in parts of the central Arctic Ocean. These anomalies appear to be driven by nonlinear interactions between thermodynamic and dynamic processes. In particular, in the Barents and Kara seas (BKS), they are a result of enhanced ice growth connected with low-temperature anomalies and the consequence of intensified atmospherically driven sea ice transport and deformations (i.e., ice divergence and shear) in this area. The Davies Strait, the east coast of Greenland and the BS regions are characterized by convergence and divergence changes connected with thinner sea ice at the ice borders along with an enhanced impact of atmospheric wind forcing. Low-pressure anomalies that developed over the eastern Arctic during JFM 2020 increased northerly winds from the cold Arctic Ocean to the BS and accelerated the southward drift of the MOSAiC ice floe. The satellite-derived and simulated sea ice velocity anomalies, which compared well during JFM 2020, indicate a strong acceleration of the Transpolar Drift relative to the mean for the past decade, with intensified speeds of up to 6 km d -1. As a consequence, sea ice transport and deformations driven by atmospheric surface wind forcing accounted for the bulk of the SIT anomalies, especially in January 2020 and February 2020. RASM intra-annual ensemble forecast simulations with 30 ensemble members forced with different atmospheric boundary conditions from 1 November 2019 through 30 April 2020 show a pronounced internal variability in the sea ice volume, driven by thermodynamic ice-growth and ice-melt processes and the impact of dynamic surface winds on sea ice formation and deformation. A comparison of the respective SIT distributions and turbulent heat fluxes during the positive AO phase in JFM 2020 and the negative AO phase in JFM 2010 corroborates the conclusion that winter sea ice conditions in the Arctic Ocean can be significantly altered by AO variability. [ABSTRACT FROM AUTHOR]

Published

2022

260. Global exposure of population and land‐use to meteorological droughts under different warming levels and SSPs: A CORDEX‐based study.

Author

Spinoni, Jonathan, Barbosa, Paulo, Bucchignani, Edoardo, Cassano, John, Cavazos, Tereza, Cescatti, Alessandro, Christensen, Jens H., Christensen, Ole B., Coppola, Erika, Evans, Jason P., Forzieri, Giovanni, Geyer, Beate, Giorgi, Filippo, Jacob, Daniela, Katzfey, Jack, Koenigk, Torben, Laprise, René, Lennard, Christopher J., Kurnaz, M. Levent, and Li, Delei

Subjects

*DROUGHT management, *DROUGHTS, *GLOBAL warming, *POPULATION forecasting, *NATURAL resources, *CLIMATE change, *DOWNSCALING (Climatology)

Abstract

Global warming is likely to cause a progressive drought increase in some regions, but how population and natural resources will be affected is still underexplored. This study focuses on global population, forests, croplands and pastures exposure to meteorological drought hazard in the 21st century, expressed as frequency and severity of drought events. As input, we use a large ensemble of climate simulations from the Coordinated Regional Climate Downscaling Experiment (CORDEX), population projections from the NASA‐SEDAC dataset and land‐use projections from the Land‐Use Harmonization 2 project for 1981–2100. The exposure to drought hazard is presented for five Shared Socioeconomic Pathways (SSP1‐SSP5) at four Global Warming Levels (GWLs: 1.5°C to 4°C). Results show that considering only Standardized Precipitation Index (SPI; based on precipitation), the SSP3 at GWL4 projects the largest fraction of the global population (14%) to experience an increase in drought frequency and severity (versus 1981–2010), with this value increasing to 60% if temperature is considered (indirectly included in the Standardized Precipitation‐Evapotranspiration Index, SPEI). With SPEI, considering the highest GWL for each SSP, 8 (for SSP2, SSP4, SSP5) and 11 (SSP3) billion people, that is, more than 90%, will be affected by at least one unprecedented drought. For SSP5 at GWL4, approximately 2 × 106 km2 of forests and croplands (respectively, 6% and 11%) and 1.5 × 106 km2 of pastures (19%) will be exposed to increased drought frequency and severity according to SPI, but for SPEI this extent will rise to 17 × 106 km2 of forests (49%), 6 × 106 km2 of pastures (78%) and 12 × 106 km2 of croplands (67%), being mid‐latitudes the most affected. The projected likely increase of drought frequency and severity significantly increases population and land‐use exposure to drought, even at low GWLs, thus extensive mitigation and adaptation efforts are needed to avoid the most severe impacts of climate change. [ABSTRACT FROM AUTHOR]

Published

2021

261. Future Global Meteorological Drought Hot Spots: A Study Based on CORDEX Data.

Author

Spinoni, Jonathan, Barbosa, Paulo, Bucchignani, Edoardo, Cassano, John, Cavazos, Tereza, Christensen, Jens H., Christensen, Ole B., Coppola, Erika, Evans, Jason, Geyer, Beate, Giorgi, Filippo, Hadjinicolaou, Panos, Jacob, Daniela, Katzfey, Jack, Koenigk, Torben, Laprise, René, Lennard, Christopher J., Kurnaz, M. Levent, Li, Delei, and Llopart, Marta

Subjects

*DROUGHTS, *DROUGHT management, *GENERAL circulation model, *DROUGHT forecasting, *CIRCULATION models, *DATABASES, *METEOROLOGICAL precipitation

Abstract

Two questions motivated this study: 1) Will meteorological droughts become more frequent and severe during the twenty-first century? 2) Given the projected global temperature rise, to what extent does the inclusion of temperature (in addition to precipitation) in drought indicators play a role in future meteorological droughts? To answer, we analyzed the changes in drought frequency, severity, and historically undocumented extreme droughts over 1981–2100, using the standardized precipitation index (SPI; including precipitation only) and standardized precipitation-evapotranspiration index (SPEI; indirectly including temperature), and under two representative concentration pathways (RCP4.5 and RCP8.5). As input data, we employed 103 high-resolution (0.44°) simulations from the Coordinated Regional Climate Downscaling Experiment (CORDEX), based on a combination of 16 global circulation models (GCMs) and 20 regional circulation models (RCMs). This is the first study on global drought projections including RCMs based on such a large ensemble of RCMs. Based on precipitation only, ~15% of the global land is likely to experience more frequent and severe droughts during 2071–2100 versus 1981–2010 for both scenarios. This increase is larger (~47% under RCP4.5, ~49% under RCP8.5) when precipitation and temperature are used. Both SPI and SPEI project more frequent and severe droughts, especially under RCP8.5, over southern South America, the Mediterranean region, southern Africa, southeastern China, Japan, and southern Australia. A decrease in drought is projected for high latitudes in Northern Hemisphere and Southeast Asia. If temperature is included, drought characteristics are projected to increase over North America, Amazonia, central Europe and Asia, the Horn of Africa, India, and central Australia; if only precipitation is considered, they are found to decrease over those areas. [ABSTRACT FROM AUTHOR]

Published

2020

262. The 13th and 14th Workshops on Antarctic Meteorology and Climate.

Author

Lazzara, Matthew A., Orendorf, Sophie A., Norton, Taylor P., Powers, Jordan G., Bromwich, David H., Carpentier, Scott, Cassano, John J., Colwell, Steven R., Cayette, Arthur M., and Werner, Kirstin

Subjects

*SCIENTIFIC literature, *ATMOSPHERIC boundary layer, *METEOROLOGICAL services, *METEOROLOGICAL research, *METEOROLOGY, *NUMERICAL weather forecasting, ANTARCTIC climate

Published

2020

263. Collaborative Research: Towards Advanced Understanding and Predictive Capability of Climate Change in the Arctic Using a High-Resolution Regional Arctic Climate Model

Author

Cassano, John [Principal Investigator]

Published

2013

264. Alexander Tall Tower! A Study of the Boundary Layer on the Ross Ice Shelf, Antarctica.

Author

Mateling, Marian E., Lazzara, Matthew A., Keller, Linda M., Weidner, George A., and Cassano, John J.

Subjects

*ATMOSPHERIC boundary layer, *SYNOPTIC climatology, *WIND speed measurement, GLACIERS & climate

Abstract

Because of the harsh weather conditions on the Antarctic continent, year-round observations of the lowlevel boundary layer must be obtained via automated data acquisition systems. Alexander Tall Tower! is an automatic weather station on the Ross Ice Shelf in Antarctica and has been operational since February 2011. At 30m tall, this station has six levels of instruments to collect environmental data, including temperature, wind speed and direction, relative humidity, and pressure. Data are collected at 30-, 15-, 7.5-, 4-, 2-, and 1-m levels above the snow surface. This study identifies short-term trends and provides an improved description of the lowest portion of the boundary layer over this portion of the Ross Ice Shelf for the February 2011-January 2014 period. Observations indicate two separate initiations of the winter season occur annually, caused by synoptic-scale anomalies. Sensible and latent heat flux estimates are computed using Monin-Obukhov similarity theory and vertical profiles of potential air temperature and wind speed. Over the three years, the monthly mean sensible heat flux ranges between 1 and 39 W m-2 (toward the surface) and the monthly mean latent heat flux ranges between -8 and 0 W m-2. Net heat fluxes directed toward the surface occur most of the year, indicating an atmospheric sink of energy. [ABSTRACT FROM AUTHOR]

Published

2018

265. Land Surface Climate in the Regional Arctic System Model.

Author

Hamman, Joseph, Nijssen, Bart, Brunke, Michael, Cassano, John, Craig, Anthony, DuVivier, Alice, Hughes, Mimi, Lettenmaier, Dennis P., Maslowski, Wieslaw, Osinski, Robert, Roberts, Andrew, and Zeng, Xubin

Subjects

*LAND surface temperature, *ARCTIC climate, *METEOROLOGICAL precipitation, *RUNOFF, *EVAPOTRANSPIRATION, *ATMOSPHERIC temperature

Abstract

The Regional Arctic System Model (RASM) is a fully coupled, regional Earth system model applied over the pan-Arctic domain. This paper discusses the implementation of the Variable Infiltration Capacity land surface model (VIC) in RASM and evaluates the ability of RASM, version 1.0, to capture key features of the land surface climate and hydrologic cycle for the period 1979-2014 in comparison with uncoupled VIC simulations, reanalysis datasets, satellite measurements, and in situ observations. RASM reproduces the dominant features of the land surface climatology in the Arctic, such as the amount and regional distribution of precipitation, the partitioning of precipitation between runoff and evapotranspiration, the effects of snow on the water and energy balance, and the differences in turbulent fluxes between the tundra and taiga biomes. Surface air temperature biases in RASM, compared to reanalysis datasets ERA-Interim and MERRA, are generally less than 2°C; however, in the cold seasons there are local biases that exceed 6°C. Compared to satellite observations, RASM captures the annual cycle of snow-covered area well, although melt progresses about two weeks faster than observations in the late spring at high latitudes. With respect to derived fluxes, such as latent heat or runoff, RASM is shown to have similar performance statistics as ERA-Interim while differing substantially from MERRA, which consistently overestimates the evaporative flux across the Arctic region. [ABSTRACT FROM AUTHOR]

Published

2016

266. Publisher Correction: Observing the Central Arctic Atmosphere and Surface with University of Colorado uncrewed aircraft systems.

Author

de Boer G, Calmer R, Jozef G, Cassano JJ, Hamilton J, Lawrence D, Borenstein S, Doddi A, Cox C, Schmale J, Preußer A, and Argrow B

Published

2024

267. The role of interdecadal climate oscillations in driving Arctic atmospheric river trends.

Author

Ma W, Wang H, Chen G, Leung LR, Lu J, Rasch PJ, Fu Q, Kravitz B, Zou Y, Cassano JJ, and Maslowski W

Abstract

Atmospheric rivers (ARs), intrusions of warm and moist air, can effectively drive weather extremes over the Arctic and trigger subsequent impact on sea ice and climate. What controls the observed multi-decadal Arctic AR trends remains unclear. Here, using multiple sources of observations and model experiments, we find that, contrary to the uniform positive trend in climate simulations, the observed Arctic AR frequency increases by twice as much over the Atlantic sector compared to the Pacific sector in 1981-2021. This discrepancy can be reconciled by the observed positive-to-negative phase shift of Interdecadal Pacific Oscillation (IPO) and the negative-to-positive phase shift of Atlantic Multidecadal Oscillation (AMO), which increase and reduce Arctic ARs over the Atlantic and Pacific sectors, respectively. Removing the influence of the IPO and AMO can reduce the projection uncertainties in near-future Arctic AR trends by about 24%, which is important for constraining projection of Arctic warming and the timing of an ice-free Arctic., (© 2024. Battelle Memorial Institute, Chen, Rasch, Fu, Kravitz, Cassano, Maslowski.)

Published

2024

268. Observing the Central Arctic Atmosphere and Surface with University of Colorado uncrewed aircraft systems.

Author

de Boer G, Calmer R, Jozef G, Cassano JJ, Hamilton J, Lawrence D, Borenstein S, Doddi A, Cox C, Schmale J, Preußer A, and Argrow B

Abstract

Over a five-month time window between March and July 2020, scientists deployed two small uncrewed aircraft systems (sUAS) to the central Arctic Ocean as part of legs three and four of the MOSAiC expedition. These sUAS were flown to measure the thermodynamic and kinematic state of the lower atmosphere, including collecting information on temperature, pressure, humidity and winds between the surface and 1 km, as well as to document ice properties, including albedo, melt pond fraction, and open water amounts. The atmospheric state flights were primarily conducted by the DataHawk2 sUAS, which was operated primarily in a profiling manner, while the surface property flights were conducted using the HELiX sUAS, which flew grid patterns, profiles, and hover flights. In total, over 120 flights were conducted and over 48 flight hours of data were collected, sampling conditions that included temperatures as low as -35 °C and as warm as 15 °C, spanning the summer melt season., (© 2022. The Author(s).)

Published

2022