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51. Application of the Multi-Scale Infrastructure for Chemistry and Aerosols version 0 (MUSICAv0) for air quality research in Africa

Author

Tang, Wenfu (author), Emmons, Louisa K. (author), Worden, Helen M. (author), Kumar, Rajesh (author), He, Cenlin (author), Gaubert, Benjamin (author), Zheng, Zhonghua (author), Tilmes, Simone (author), Levelt, Pieternel Felicitas (author), Tang, Wenfu (author), Emmons, Louisa K. (author), Worden, Helen M. (author), Kumar, Rajesh (author), He, Cenlin (author), Gaubert, Benjamin (author), Zheng, Zhonghua (author), Tilmes, Simone (author), and Levelt, Pieternel Felicitas (author)

Abstract

The Multi-Scale Infrastructure for Chemistry and Aerosols Version 0 (MUSICAv0) is a new community modeling infrastructure that enables the study of atmospheric composition and chemistry across all relevant scales. We develop a MUSICAv0 grid with Africa refinement (∼ 28 km × 28 km over Africa). We evaluate the MUSICAv0 simulation for 2017 with in situ observations and compare the model results to satellite products over Africa. A simulation from the Weather Research and Forecasting model coupled with Chemistry (WRF-Chem), a regional model that is widely used in Africa studies, is also included in the analyses as a reference. Overall, the performance of MUSICAv0 is comparable to WRF-Chem. Both models underestimate carbon monoxide (CO) compared to in situ observations and satellite CO column retrievals from the Measurements of Pollution in the Troposphere (MOPITT) satellite instrument. MUSICAv0 tends to overestimate ozone (O3), likely due to overestimated stratosphere-to-troposphere flux of ozone. Both models significantly underestimate fine particulate matter (PM2.5) at two surface sites in East Africa. The MUSICAv0 simulation agrees better with aerosol optical depth (AOD) retrievals from the Moderate Resolution Imaging Spectroradiometer (MODIS) and tropospheric nitrogen dioxide (NO2) column retrievals from the Ozone Monitoring Instrument (OMI) than WRF-Chem. MUSICAv0 has a consistently lower tropospheric formaldehyde (HCHO) column than OMI retrievals. Based on model–satellite discrepancies between MUSICAv0 and WRF-Chem and MOPITT CO, MODIS AOD, and OMI tropospheric NO2, we find that future field campaign(s) and more in situ observations in the East African region (5∘ S–5∘ N, 30–45∘ E) could substantially improve the predictive skill of atmospheric chemistry model(s). This suggested focus region exhibits the largest model–in situ observation discrepancies, as well as targets for high population density, land cover variability, and anthropogenic pollution sources., Atmospheric Remote Sensing

Published
2023
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52. Enhancing the Community Noah-MP Land Model Capabilities for Earth Sciences and Applications

Author

He, Cenlin, Chen, Fei, Barlage, Michael, Yang, Zong-Liang, Wegiel, Jerry W., Niu, Guo-Yue, Gochis, David, Mocko, David M., Abolafia-Rosenzweig, Ronnie, Zhang, Zhe, Lin, Tzu-Shun, Valayamkunnath, Prasanth, Ek, Michael, Niyogi, Dev, He, Cenlin, Chen, Fei, Barlage, Michael, Yang, Zong-Liang, Wegiel, Jerry W., Niu, Guo-Yue, Gochis, David, Mocko, David M., Abolafia-Rosenzweig, Ronnie, Zhang, Zhe, Lin, Tzu-Shun, Valayamkunnath, Prasanth, Ek, Michael, and Niyogi, Dev

Published
2023

54. High Resolution Forecasting of Summer Drought in the Western United States

Author

Abolafia-Rosenzweig, Ronnie, He, Cenlin, Chen, Fei, Ikeda, Kyoko, Schneider, Timothy, Rasmussen, Roy, Abolafia-Rosenzweig, Ronnie, He, Cenlin, Chen, Fei, Ikeda, Kyoko, Schneider, Timothy, and Rasmussen, Roy

Abstract

Drought monitoring and forecasting systems are used in the United States (U.S.) to inform drought management decisions. Drought forecasting efforts have often been conducted and evaluated at coarse spatial resolutions (i.e., >10-km), which miss key local drought information at higher resolutions. Addressing the importance of forecasting drought at high resolutions, this study develops statistical models to evaluate 1- to 3-month lead time predictability of meteorological and agricultural summer drought across the western U.S. at a 4-km resolution. Our high-resolution drought predictions have statistically significant skill (p ≤ 0.05) across 70%–100% of the western U.S., varying by evaluation metric and lead time. 1- to 3-month lead time drought forecasts accurately represent monitored summer drought spatial patterns during major drought events, the interannual variability of drought area from 1982 to 2020 (r = 0.84–0.93), and drought trends (r = 0.94–0.97). 71% of western U.S summer drought area interannual variability can be explained by cold-season (November–February) climate conditions alone allowing skillful 3-month lead time predictions. Pre-summer drought conditions (represented by drought indices) are the most important predictors for summer drought. Thus, the statistical models developed in this study heavily rely on the autocorrelation of chosen agricultural and meteorological drought indices which estimate land surface moisture memory. Indeed, prediction skill strongly correlates with persistence of drought conditions (r ≥ 0.73). This study is intended to support future development of operational drought early warning systems that inform drought management. © 2023. The Authors.

Published
2023

55. Modernizing the open-source community Noah with multi-parameterization options (Noah-MP) land surface model (version 5.0) with enhanced modularity, interoperability, and applicability

Author

He, Cenlin, Valayamkunnath, Prasanth, Barlage, Michael, Chen, Fei, Gochis, David, Cabell, Ryan, Schneider, Tim, Rasmussen, Roy, Niu, Guo-Yue, Yang, Zong-Liang, Niyogi, Dev, Ek, Michael, He, Cenlin, Valayamkunnath, Prasanth, Barlage, Michael, Chen, Fei, Gochis, David, Cabell, Ryan, Schneider, Tim, Rasmussen, Roy, Niu, Guo-Yue, Yang, Zong-Liang, Niyogi, Dev, and Ek, Michael

Abstract

The widely used open-source community Noah with multi-parameterization options (Noah-MP) land surface model (LSM) is designed for applications ranging from uncoupled land surface hydrometeorological and ecohydrological process studies to coupled numerical weather prediction and decadal global or regional climate simulations. It has been used in many coupled community weather, climate, and hydrology models. In this study, we modernize and refactor the Noah-MP LSM by adopting modern Fortran code standards and data structures, which substantially enhance the model modularity, interoperability, and applicability. The modernized Noah-MP is released as the version 5.0 (v5.0), which has five key features: (1) enhanced modularization as a result of re-organizing model physics into individual process-level Fortran module files, (2) an enhanced data structure with new hierarchical data types and optimized variable declaration and initialization structures, (3) an enhanced code structure and calling workflow as a result of leveraging the new data structure and modularization, (4) enhanced (descriptive and self-explanatory) model variable naming standards, and (5) enhanced driver and interface structures to be coupled with the host weather, climate, and hydrology models. In addition, we create a comprehensive technical documentation of the Noah-MP v5.0 and a set of model benchmark and reference datasets. The Noah-MP v5.0 will be coupled to various weather, climate, and hydrology models in the future. Overall, the modernized Noah-MP allows a more efficient and convenient process for future model developments and applications.

Published
2023

56. Tracking Urban Footprint on Extreme Precipitation in an African Megacity

Author

Doan, Quang-Van, Kobayashi, Shun, Kusaka, Hiroyuki, Chen, Fei, He, Cenlin, Niyogi, Dev, Doan, Quang-Van, Kobayashi, Shun, Kusaka, Hiroyuki, Chen, Fei, He, Cenlin, and Niyogi, Dev

Abstract

This study contributes to the body of current knowledge about the urban effect on extreme precipitation (EP) by investigating the city–EP interaction over Lagos, Nigeria. This is a unique, first-time study that adds a “missing piece” of this information about the African continent to the comprehensive global urban precipitation “puzzle.” The convection-permitting Weather Research and Forecasting (WRF) Model is employed within an ensemble simulation framework using combinations of different physical schemes and boundary/initial conditions to detect the urban signal on an extreme rainfall event that occurred on 30 May 2006. WRF simulations are verified against satellite-estimated and in situ observations, and the results from the best-performing ensemble members are used for analysis. The results show that the control simulation with urban representation generated 20%–30% more rainfall over the urban area than the nonurban sensitivity simulation, in which the city is replaced by forest. Physical mechanisms behind the differences were revealed. We found that the urbanization in Lagos reduced evapotranspiration, resulting in the increase of sensible heating (by 75 W m-2). This further enhances the urban heat-island effect (+1.5 K of air surface temperature), facilitating horizontal convergence and boosting daytime sea breeze. As a result, more moisture is transported from the southern sea area to inland areas; the moisture then converges over Lagos city, creating favorable conditions for enhancing convection and extreme-rainfall-generating processes. © 2023 American Meteorological Society.

Published
2023

59. Comprehensive Evaluation of Spatial Distribution and Temporal Trend of NO 2 , SO 2 and AOD Using Satellite Observations over South and East Asia from 2011 to 2021.

Author

Rahman, Md Masudur, Wang, Shuo, Zhao, Weixiong, Arshad, Arfan, Zhang, Weijun, and He, Cenlin

Subjects
AIR pollution control, AIR pollutants, AIR quality monitoring, AIR pollution, AIR quality, NITROGEN dioxide, POLLUTANTS
Abstract

The past decade has witnessed remarkable economic development, marked by rapid industrialization and urbanization across Asian regions. This surge in economic activity has led to significant emissions, resulting in alarming levels of air pollution. Our study comprehensively assessed the spatial and temporal trends of key pollutants, namely nitrogen dioxide (NO2), sulfur dioxide (SO2), and aerosol (using aerosol optical depth (AOD) at 550 nm as an indicator), from 2011 to 2021. The data sources utilized include OMI onboard the Aura satellite for NO2 and SO2, as well as MODIS onboard Terra and Aqua satellites for AOD. The results from spatial and temporal trend analyses of the three parameters show that there is a clear declining trend over China and Republic of Korea (e.g., NO2 is declining with an overall rate of −7.8 × 1012 molecules/cm2/year over China) due to the strict implementation of air pollution control policies. However, it is essential to note that both countries still grapple with substantial pollution levels, with proportions exceeding 0.5, indicating that air quality is improving but has not yet reached a safe threshold. In contrast, South Asian regions, including Bangladesh, Pakistan, and India, are experiencing an increasing trend (e.g., NO2 is increasing with an overall rate of 1.2 × 1012 molecules/cm2/year in Bangladesh), primarily due to the lack of rigorous air pollution control policies. The average emissions of NO2 and SO2 were remarkably higher in winter than in summer. Notably, the identified hotspots are statistically significant and predominantly coincide with densely populated areas, such as the North China Plain (NCP). Furthermore, this study underscores the pivotal role of sector-wise emissions in air quality monitoring and improvement. Different cities are primarily influenced by emissions from specific sectors, emphasizing the need for targeted pollution control measures. The findings presented in this research contribute valuable insights to the air quality monitoring and improvement efforts in East and South Asian regions. [ABSTRACT FROM AUTHOR]

Published
2023
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67. Improving snow albedo modeling in the E3SM land model (version 2.0) and assessing its impacts on snow and surface fluxes over the Tibetan Plateau

Author

Hao, Dalei, primary, Bisht, Gautam, additional, Rittger, Karl, additional, Bair, Edward, additional, He, Cenlin, additional, Huang, Huilin, additional, Dang, Cheng, additional, Stillinger, Timbo, additional, Gu, Yu, additional, Wang, Hailong, additional, Qian, Yun, additional, and Leung, L. Ruby, additional

Published
2023
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70. Technical documentation for the hybrid 100-m global land cover dataset with Local Climate Zones for WRF

Author

Demuzere, Matthias, He, Cenlin, Martilli, Alberto, and Zonato, Andrea

Subjects
MODIS Land Cover, Weather Research and Forecasting (WRF) model, Copernicus Global Land Service Land Cover, WPS Preprocessing, Local Climate Zones
Abstract

This technical documentation describes the development of a hybrid 100-m global land cover dataset and itsimplementation in the state-of-the-art Weather Research and Forecasting (WRF) model version4.5. This hybrid CGLC-MODIS-LCZ dataset is based on 1) the Copernicus Global Land ServiceLand Cover (CGLC) product resampled to MODIS IGBP classes (CGLC-MODIS), and 2) the globalmap of Local Climate Zones (LCZ) that describes the heterogeneous urban land surface. Both theCGLC and LCZ products are available at a 100-m spatial resolution, are representative for the year2018, and cover -180°W to 180°E and -60°S to 78°N. Remaining areas are filled with the MODISland cover classes. This dataset has been implemented into the WRF Preprocessing System(WPS) as tiled binary data files with a new GEOGRID table entry to allow WRF/WPS users toflexibly use this dataset in their studies particularly relevant for urban modeling applications. The corresponding dataset can be found at:https://doi.org/10.5281/zenodo.7670653.

Published
2023
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77. Effects of Fire Diurnal Variation and Plume Rise on U.S. Air Quality During FIREX‐AQ and WE‐CAN Based on the Multi‐Scale Infrastructure for Chemistry and Aerosols (MUSICAv0)

Author

Tang, Wenfu, primary, Emmons, Louisa K., additional, Buchholz, Rebecca R., additional, Wiedinmyer, Christine, additional, Schwantes, Rebecca H., additional, He, Cenlin, additional, Kumar, Rajesh, additional, Pfister, Gabriele G., additional, Worden, Helen M., additional, Hornbrook, Rebecca S., additional, Apel, Eric C., additional, Tilmes, Simone, additional, Gaubert, Benjamin, additional, Martinez‐Alonso, Sara‐Eva, additional, Lacey, Forrest, additional, Holmes, Christopher D., additional, Diskin, Glenn S., additional, Bourgeois, Ilann, additional, Peischl, Jeff, additional, Ryerson, Thomas B., additional, Hair, Johnathan W., additional, Weinheimer, Andrew J., additional, Montzka, Denise D., additional, Tyndall, Geoffrey S., additional, and Campos, Teresa L., additional

Published
2022
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83. Climatic Effects of Black Carbon Aerosols over the Tibetan Plateau

Author

He, Cenlin

Subjects
Atmospheric sciences, black carbon, climatic effects, radiative forcing, regional warming, Tibetan Plateau
Abstract

Black carbon (BC), also known as soot, has been identified as the second most important anthropogenic emissions in terms of global climate forcing in the current atmosphere. Ample evidence has shown that BC deposition is an important driver of rapid snow melting and glacier retreat over the Tibetan Plateau, which holds the largest snow/ice mass outside polar regions. However, the climatic effects of BC over the Tibetan Plateau have not been thoroughly investigated in such a manner as to understand, quantify, and reduce large uncertainties in the estimate of radiative and hydrological effects. Thus, this Ph.D. study seeks to understand and improve key processes controlling BC life cycle in global and regional models and to quantify BC radiative effects over the Tibetan Plateau. First, the capability of a state-of-the-art global chemical transport model (CTM), GEOS-Chem, and the associated model uncertainties are systematically evaluated in simulating BC over the Tibetan Plateau, using in situ measurements of BC in surface air, BC in snow, and BC absorption optical depth. The effects of three key factors on the simulation are also delineated, including Asian anthropogenic emissions, BC aging process, and model resolution. Subsequently, a microphysics-based BC aging scheme that accounts for condensation, coagulation, and heterogeneous chemical oxidation processes is developed and examined in GEOS-Chem by comparing with aircraft measurements. Compared to the default aging scheme, the microphysical scheme reduces model-observation discrepancies by a factor of ~3, particularly in the middle and upper troposphere. In addition, a theoretical BC aging-optics model is developed to account for three typical evolution stages, namely, freshly emitted aggregates, coated BC by soluble material, and BC particles undergoing further hygroscopic growth. The geometric-optics surface-wave (GOS) approach is employed to compute the BC single-scattering properties at each aging stage, which are subsequently compared with laboratory measurements. Results show large variations in BC optical properties caused by coating morphology and aging stages. Furthermore, a comprehensive intercomparison of the GOS approach, the superposition T-matrix method, and laboratory measurements is performed for optical properties of BC with complex structures during aging. Moreover, a new snow albedo model is developed for widely-observed close-packed snow grains internally mixed with BC. Results indicate that albedo simulations that account for snow close packing match closer to observations. Close packing enhances BC-induced snow albedo reduction and associated surface radiative forcing by up to 15% (20%) for fresh (old) snow, which suggests that BC-snow albedo forcing is underestimated in previous modeling studies without accounting for close packing. Finally, the snow albedo forcing and direct radiative forcing (DRF) of BC in the Tibetan Plateau are estimated using GEOS-Chem in conjunction with a stochastic snow model and a radiative transfer model. This, for the first time, accounts for realistic non-spherical snow grain shape and stochastic multiple inclusions of BC within snow in assessing BC-snow interactions. The annual mean BC snow albedo forcing is 2.9 W m-2 over snow-covered Plateau regions. BC-snow internal mixing increases the albedo forcing by 40-60% compared with external mixing, whereas Koch snowflakes reduce the forcing by 20-40% relative to spherical snow grains. BC DRF at the top of the atmosphere is 2.3 W m-2 with uncertainties of -70% - +85% in the Plateau. The BC forcings are further attributed to emissions from different regions.

Published
2017

84. Winter and spring climate explains a large portion of interannual variability and trend in western U.S. summer fire burned area

Author

Abolafia-Rosenzweig, Ronnie, He, Cenlin, Chen, Fei, Abolafia-Rosenzweig, Ronnie, He, Cenlin, and Chen, Fei

Abstract

This study predicts summer (June–September) fire burned area across the western United States (U.S.) from 1984 to 2020 using ensembles of statistical models trained with pre-fire season climate conditions. Winter and spring climate conditions alone explain up to 53% of the interannual variability and 58% of the increasing trend of observed summer burned area, which suggests that climate conditions in antecedent seasons have been an important driver to broad-scale changes in summer fire activity in the western U.S. over the recent four decades. Relationships between antecedent climate conditions with summer burned area are found to be strongest over non-forested and middle-to-high elevation areas (1100–3300 m). Statistical models that predict summer burned area using both antecedent and fireseason climate conditions have improved performance, explaining 69% of the interannual variability and 83% of the increasing trend of observed burned area. Among the antecedent climate predictors, vapor pressure deficit averaged over winter and spring plays the most critical role in predicting summer fire burned area. Spring snow drought area is found to be an important antecedent predictor for summer burned area over snow-reliant regions in the nonlinear statistical modeling framework used in this analysis. Namely, spring snow drought memory is realized through dry anomalies in land (soil and fuel) and atmospheric moisture during summer, which favours fire activity. This study highlights the important role of snow drought in subseasonal-to-seasonal forecasts of summer burned area over snow-reliant areas. © 2022 The Author(s). Published by IOP Publishing Ltd

Published
2022

85. Evaluation and Optimization of Snow Albedo Scheme in Noah-MP Land Surface Model Using In Situ Spectral Observations in the Colorado Rockies

Author

Abolafia-Rosenzweig, Ronnie, He, Cenlin, McKenzie Skiles, S., Chen, Fei, Gochis, David, Abolafia-Rosenzweig, Ronnie, He, Cenlin, McKenzie Skiles, S., Chen, Fei, and Gochis, David

Abstract

The Biosphere-Atmosphere Transfer Scheme (BATS) ground snow albedo algorithm is commonly used in land-surface models (LSM), weather forecasting and research applications. This study addresses key uncertainties in BATS simulated ground snow albedo within the Noah-MP LSM framework through evaluation and optimization of the Noah-MP BATS ground snow albedo formulation using 2-band (visible and near-infrared (NIR)) in situ albedo observations at Rocky Mountain field stations. The Noah-MP BATS ground snow albedo scheme is extremely sensitive to its input parameters. Namely, an ensemble generated by varying BATS input parameters within potentially plausible ranges provides an average daily range (maximum ensemble member minus minimum ensemble member) of ground snow albedo exceeding 0.45 in visible and NIR bands. Parameter optimization improves agreement between simulated and in situ observed ground snow albedo in visible, NIR and broadband spectrums. Importantly, optimized parameters result in reduced biases relative to observed fresh-snow albedo and better agreement with observed albedo decay. Our analysis across different sites supports that the optimized BATS ground snow albedo parameters are appropriate to transfer in space and time, at least within the region studied (the central-southern Rocky Mountains). The primary error source remaining after parameter optimization is that observed fresh-snow albedo is highly variable, particularly in the NIR spectrum, whereas BATS fresh-snow albedo is constant, an issue which requires further investigation. This study shows significant correlations between observed fresh-snow albedo and surface meteorological conditions (e.g., downward shortwave radiation and temperature) which can support future model development that attempts to include a time-varying formulation for fresh-snow albedo. © 2022 The Authors. Journal of Advances in Modeling Earth Systems published by Wiley Periodicals LLC on behalf of American Geophysical Union.

Published
2022

86. Application of the Multi-Scale Infrastructure for Chemistry and Aerosols version 0 (MUSICAv0) for air quality in Africa.

Author

Wenfu Tang, Emmons, Louisa K., Worden, Helen M., Kumar, Rajesh, He, Cenlin, Gaubert, Benjamin, Zhonghua Zheng, Tilmes, Simone, Buchholz, Rebecca R., Martinez-Alonso, Sara-Eva, Granier, Claire, Soulie, Antonin, McKain, Kathryn, Daube, Bruce C., Peischl, Jeff, Thompson, Chelsea, and Levelt, Pieternel

Subjects
TROPOSPHERIC aerosols, MODIS (Spectroradiometer), AIR quality, ATMOSPHERIC chemistry, AEROSOLS, CHEMICAL models
Abstract

The Multi-Scale Infrastructure for Chemistry and Aerosols Version 0 (MUSICAv0) is a new community modeling infrastructure that enables the study of atmospheric composition and chemistry across all relevant scales. We develop a MUSICAv0 grid with Africa refinement (~28 km x 28 km over Africa). We evaluate the MUSICAv0 simulation for 2017 with in situ observations and compare the model results to satellite products over Africa. A simulation from the Weather Research and Forecasting model coupled with Chemistry (WRF-Chem), a regional model that is widely used in Africa studies, is also included in the analyses as a reference. Overall, the performance of MUSICAv0 is comparable to WRF-Chem. Both models underestimate carbon monoxide (CO) compared to in situ observations and satellite CO column retrievals from the Measurements of Pollution in the Troposphere (MOPITT) satellite instrument. MUSICAv0 tends to overestimate ozone (O3), likely due to overestimated stratosphere-to-troposphere flux of ozone. Both models significantly underestimate fine particulate matter (PM2.5) at two surface sites in East Africa. The MUSICAv0 simulation agrees better with aerosol optical depth (AOD) retrievals from the Moderate Resolution Imaging Spectroradiometer (MODIS) and tropospheric nitrogen dioxide (NO2) column retrievals from the Ozone Monitoring Instrument (OMI) than WRF-Chem. MUSICAv0 has a consistently lower tropospheric formaldehyde (HCHO) column than OMI retrievals. Based on model-satellite discrepancies between MUSICAv0 and WRF-Chem and MOPITT CO, MODIS AOD, and OMI tropospheric NO2, we find that future field campaign(s) and more in situ observations in an East African region (30°E - 45°E, 5°S - 5°N) could substantially improve the predictive skill of atmospheric chemistry model(s). This suggested focus region exhibits the largest model-in situ observation discrepancies, as well as targets for high population density, land cover variability, and anthropogenic pollution sources. [ABSTRACT FROM AUTHOR]

Published
2023
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87. Impact of solar geoengineering on wildfires in the 21st century in CESM2/WACCM6.

Author

Tang, Wenfu, Tilmes, Simone, Lawrence, David M., Li, Fang, He, Cenlin, Emmons, Louisa K., Buchholz, Rebecca R., and Xia, Lili

Subjects
ENVIRONMENTAL engineering, GLOBAL warming, STRATOSPHERIC aerosols, TWENTY-first century, SULFATE aerosols, FOREST fires, WILDFIRE prevention, FUEL reduction (Wildfire prevention)
Abstract

We quantify future changes in wildfire burned area and carbon emissions in the 21st century under four Shared Socioeconomic Pathways (SSPs) scenarios and two SSP5-8.5-based solar geoengineering scenarios with a target surface temperature defined by SSP2-4.5 – solar irradiance reduction (G6solar) and stratospheric sulfate aerosol injections (G6sulfur) – and explore the mechanisms that drive solar geoengineering impacts on fires. This study is based on fully coupled climate–chemistry simulations with simulated occurrence of fires (burned area and carbon emissions) using the Whole Atmosphere Community Climate Model version 6 (WACCM6) as the atmospheric component of the Community Earth System Model version 2 (CESM2). Globally, total wildfire burned area is projected to increase over the 21st century under scenarios without geoengineering and decrease under the two geoengineering scenarios. By the end of the century, the two geoengineering scenarios have lower burned area and fire carbon emissions than not only their base-climate scenario SSP5-8.5 but also the targeted-climate scenario SSP2-4.5. Geoengineering reduces wildfire occurrence by decreasing surface temperature and wind speed and increasing relative humidity and soil water, with the exception of boreal regions where geoengineering increases the occurrence of wildfires due to a decrease in relative humidity and soil water compared with the present day. This leads to a global reduction in burned area and fire carbon emissions by the end of the century relative to their base-climate scenario SSP5-8.5. However, geoengineering also yields reductions in precipitation compared with a warming climate, which offsets some of the fire reduction. Overall, the impacts of the different driving factors are larger on burned area than fire carbon emissions. In general, the stratospheric sulfate aerosol approach has a stronger fire-reducing effect than the solar irradiance reduction approach. [ABSTRACT FROM AUTHOR]

Published
2023
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88. Modernizing the open-source community Noah-MP land surface model (version 5.0) with enhanced modularity, interoperability, and applicability.

Author

He, Cenlin, Valayamkunnath, Prasanth, Barlage, Michael, Chen, Fei, Gochis, David, Cabell, Ryan, Schneider, Tim, Rasmussen, Roy, Niu, Guo-Yue, Yang, Zong-Liang, Niyogi, Dev, and Ek, Michael

Subjects
ECOHYDROLOGY, DATA structures, NUMERICAL weather forecasting, HYDROLOGIC models, INTERFACE structures, MODULAR design
Abstract

The widely-used open-source community Noah-MP land surface model (LSM) is designed for applications ranging from uncoupled land-surface and ecohydrological process studies to coupled numerical weather prediction and decadal global/regional climate simulations. It has been used in many coupled community weather/climate/hydrology models. In this study, we modernize/refactor the Noah-MP LSM by adopting modern Fortran code and data structures and standards, which substantially enhances the model modularity, interoperability, and applicability. The modernized Noah-MP is released as the version 5.0 (v5.0), which has five key features: (1) enhanced modularization and interoperability by re-organizing model physics into individual process-level Fortran module files, (2) enhanced data structure with new hierarchical data types and optimized variable declaration and initialization structures, (3) enhanced code structure and calling workflow by leveraging the new data structure and modularization, (4) enhanced (descriptive and self-explanatory) model variable naming standard, and (5) enhanced driver and interface structures to couple with host weather/climate/hydrology models. In addition, we create a comprehensive technical documentation of the Noah-MP v5.0 and a set of model benchmark and reference datasets. The Noah-MP v5.0 will be coupled to various weather/climate/hydrology models in the future. Overall, the modernized Noah-MP will allow a more efficient and convenient process for future model developments and applications. [ABSTRACT FROM AUTHOR]

Published
2023
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90. Supplementary material to "Improving snow albedo modeling in E3SM land model (version 2.0) and assessing its impacts on snow and surface fluxes over the Tibetan Plateau"

Author

Hao, Dalei, primary, Bisht, Gautam, additional, He, Cenlin, additional, Bair, Edward, additional, Huang, Huilin, additional, Dang, Cheng, additional, Rittger, Karl, additional, Gu, Yu, additional, Wang, Hailong, additional, Qian, Yun, additional, and Leung, L. Ruby, additional

Published
2022
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94. Contributions of Traffic and Industrial Emission Reductions to the Air Quality Improvement after the Lockdown of Wuhan and Neighboring Cities Due to COVID-19

Author

Feng, Xiaoxiao, Zhang, Xiaole, He, Cenlin, and Wang, Jing

Subjects
air quality, COVID-19, emission inventory, WRF-CMAQ model, sensitivity analysis, restriction policy
Abstract

Wuhan was locked down from 23 January to 8 April 2020 to prevent the spread of the novel coronavirus disease 2019 (COVID-19). Both public and private transportation in Wuhan and its neighboring cities in Hubei Province were suspended or restricted, and the manufacturing industry was partially shut down. This study collected and investigated ground monitoring data to prove that the lockdowns of the cities had significant influences on the air quality in Wuhan. The WRF-CMAQ (Weather Research and Forecasting-Community Multiscale Air Quality) model was used to evaluate the emission reduction from transportation and industry sectors and associated air quality impact. The results indicate that the reduction in traffic emission was nearly 100% immediately after the lockdown between 23 January and 8 February and that the industrial emission tended to decrease by about 50% during the same period. The industrial emission further deceased after 9 February. Emission reduction from transportation and that from industry was not simultaneous. The results imply that the shutdown of industry contributed significantly more to the pollutant reduction than the restricted transportation.

Published
2021

98. SNICAR-ADv3: a community tool for modeling spectral snow albedo

Author

Flanner, Mark G., primary, Arnheim, Julian B., additional, Cook, Joseph M., additional, Dang, Cheng, additional, He, Cenlin, additional, Huang, Xianglei, additional, Singh, Deepak, additional, Skiles, S. McKenzie, additional, Whicker, Chloe A., additional, and Zender, Charles S., additional

Published
2021
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