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2. Evaluating the Water Cycle Over CONUS at the Watershed Scale for the Energy Exascale Earth System Model Version 1 (E3SMv1) Across Resolutions

Author

Harrop, Bryce E, Balaguru, Karthik, Golaz, Jean‐Christophe, Leung, L Ruby, Mahajan, Salil, Rhoades, Alan M, Ullrich, Paul A, Zhang, Chengzhu, Zheng, Xue, Zhou, Tian, Caldwell, Peter M, Keen, Noel D, and Mametjanov, Azamat

Subjects
Hydrology, Atmospheric Sciences, Earth Sciences, Atmospheric sciences, Geoinformatics
Abstract

The water cycle is an important component of the earth system and it plays a key role in many facets of society, including energy production, agriculture, and human health and safety. In this study, the Energy Exascale Earth System Model version 1 (E3SMv1) is run with low-resolution (roughly 110 km) and high-resolution (roughly 25 km) configurations—as established by the High Resolution Model Intercomparison Project protocol—to evaluate the atmospheric and terrestrial water budgets over the conterminous United States (CONUS) at the large watershed scale. The warm season water cycle slows down in the HR experiment relative to the LR, with decreasing fluxes of precipitation, evapotranspiration, atmospheric moisture convergence, and runoff. The reductions in these terms exacerbate biases for some watersheds, while reducing them in others. For example, precipitation biases are exacerbated at HR over the Eastern and Central CONUS watersheds, while precipitation biases are reduced at HR over the Western CONUS watersheds. The most pronounced changes with resolution to the water cycle come from reductions in precipitation and evapotranspiration. The reduction in evapotranspiration reduces the biases across nearly all of the CONUS. Additional exploratory metrics show improvements to water cycle extremes (both in precipitation and streamflow), fractional contributions of different storm types to total precipitation, and mountain snowpack.

Published
2023

4. Use-Inspired, Process-Oriented GCM Selection: Prioritizing Models for Regional Dynamical Downscaling

Author

Goldenson, Naomi, Leung, L Ruby, Mearns, Linda O, Pierce, David W, Reed, Kevin A, Simpson, Isla R, Ullrich, Paul, Krantz, Will, Hall, Alex, Jones, Andrew, and Rahimi, Stefan

Subjects
Earth Sciences, Atmospheric Sciences, Climate Action, Downscaling, Climate models, Model comparison, Regional models, Decision support, Astronomical and Space Sciences, Physical Geography and Environmental Geoscience, Meteorology & Atmospheric Sciences, Atmospheric sciences, Climate change science
Abstract

Dynamical downscaling is a crucial process for providing regional climate information for broad uses, using coarser-resolution global models to drive higher-resolution regional climate simulations. The pool of global climate models (GCMs) providing the fields needed for dynamical downscaling has increased from the previous generations of the Coupled Model Intercomparison Project (CMIP). However, with limited computational resources, the need for prioritizing the GCMs for subsequent downscaling studies remains. GCM selection for dynamical downscaling should focus on evaluating processes relevant for providing boundary conditions to the regional models and be inspired by regional uses such as the response of extremes to changes in the boundary conditions. This leads to the need for metrics representing processes of relevance to diverse stakeholders and subregions of a domain. Procedures to account for metric redundancy and the statistical distinguishability of GCM rankings are required. Further, procedures for selecting realizations from ensembles of top-performing GCM simulations can be used to span the range of climate change signals in multiple ways. As a result, distinct weighting of metrics and prioritization of particular realizations may depend on user needs. We provide high-level guidelines for such region-specific evaluations and address how CMIP7 might enable dynamical downscaling of a representative sample of high-quality models across representative shared socioeconomic pathways (SSPs).

Published
2023

7. Increased U.S. coastal hurricane risk under climate change

Author

Balaguru, Karthik, Xu, Wenwei, Chang, Chuan-Chieh, Leung, L Ruby, Judi, David R, Hagos, Samson M, Wehner, Michael F, Kossin, James P, and Ting, Mingfang

Subjects
Climate-Related Exposures and Conditions, Climate Action
Abstract

Several pathways for how climate change may influence the U.S. coastal hurricane risk have been proposed, but the physical mechanisms and possible connections between various pathways remain unclear. Here, future projections of hurricane activity (1980-2100), downscaled from multiple climate models using a synthetic hurricane model, show an enhanced hurricane frequency for the Gulf and lower East coast regions. The increase in coastal hurricane frequency is driven primarily by changes in steering flow, which can be attributed to the development of an upper-level cyclonic circulation over the western Atlantic. The latter is part of the baroclinic stationary Rossby waves forced mainly by increased diabatic heating in the eastern tropical Pacific, a robust signal across the multimodel ensemble. Last, these heating changes also play a key role in decreasing wind shear near the U.S. coast, further aggravating coastal hurricane risk enhanced by the physically connected steering flow changes.

Published
2023

8. Biomass-burning smoke's properties and its interactions with marine stratocumulus clouds in WRF-CAM5 and southeastern Atlantic field campaigns

Author

Howes, Calvin, Saide, Pablo E, Coe, Hugh, Dobracki, Amie, Freitag, Steffen, Haywood, Jim M, Howell, Steven G, Gupta, Siddhant, Uin, Janek, Kacarab, Mary, Kuang, Chongai, Leung, L Ruby, Nenes, Athanasios, McFarquhar, Greg M, Podolske, James, Redemann, Jens, Sedlacek, Arthur J, Thornhill, Kenneth L, Wong, Jenny PS, Wood, Robert, Wu, Huihui, Zhang, Yang, Zhang, Jianhao, and Zuidema, Paquita

Subjects
Earth Sciences, Atmospheric Sciences, Climate Action, Astronomical and Space Sciences, Meteorology & Atmospheric Sciences, Atmospheric sciences, Climate change science
Abstract

A large part of the uncertainty in climate projections comes from uncertain aerosol properties and aerosol-cloud interactions as well as the difficulty in remotely sensing them. The southeastern Atlantic functions as a natural laboratory to study biomass-burning smoke and to constrain this uncertainty. We address these gaps by comparing the Weather Research and Forecasting with Chemistry Community Atmosphere Model (WRF-CAM5) to the multi-campaign observations ORACLES (ObseRvations of Aerosols above CLouds and their intEractionS), CLARIFY (CLoud-Aerosol-Radiation Interaction and Forcing), and LASIC (Layered Atlantic Smoke Interactions with Clouds) in the southeastern Atlantic in August 2017 to evaluate a large range of the model's aerosol chemical properties, size distributions, processes, and transport, as well as aerosol-cloud interactions. Overall, while WRF-CAM5 is able to represent smoke properties and transport, some key discrepancies highlight the need for further analysis. Observations of smoke composition show an overall decrease in aerosol mean diameter as smoke ages over 4-12 d, while the model lacks this trend. A decrease in the mass ratio of organic aerosol (OA) to black carbon (BC), OA:BC, and the OA mass to carbon monoxide (CO) mixing ratio, OA:CO, suggests that the model is missing processes that selectively remove OA from the particle phase, such as photolysis and heterogeneous aerosol chemistry. A large (factor of ∼2.5) enhancement in sulfate from the free troposphere (FT) to the boundary layer (BL) in observations is not present in the model, pointing to the importance of properly representing secondary sulfate aerosol formation from marine dimethyl sulfide and gaseous SO2 smoke emissions. The model shows a persistent overprediction of aerosols in the marine boundary layer (MBL), especially for clean conditions, which multiple pieces of evidence link to weaker aerosol removal in the modeled MBL than reality. This evidence includes several model features, such as not representing observed shifts towards smaller aerosol diameters, inaccurate concentration ratios of carbon monoxide and black carbon, underprediction of heavy rain events, and little evidence of persistent biases in modeled entrainment. The average below-cloud aerosol activation fraction (NCLD/NAER) remains relatively constant in WRF-CAM5 between field campaigns (∼0.65), while it decreases substantially in observations from ORACLES (∼0.78) to CLARIFY (∼0.5), which could be due to the model misrepresentation of clean aerosol conditions. WRF-CAM5 also overshoots an observed upper limit on liquid cloud droplet concentration around NCLDCombining double low line 400-500 cm-3 and overpredicts the spread in NCLD. This could be related to the model often drastically overestimating the strength of boundary layer vertical turbulence by up to a factor of 10. We expect these results to motivate similar evaluations of other modeling systems and promote model development to reduce critical uncertainties in climate simulations. Copyright:

Published
2023

9. The fully coupled regionally refined model of E3SM version 2: overview of the atmosphere, land, and river results

Author

Tang, Qi, Golaz, Jean-Christophe, Van Roekel, Luke P, Taylor, Mark A, Lin, Wuyin, Hillman, Benjamin R, Ullrich, Paul A, Bradley, Andrew M, Guba, Oksana, Wolfe, Jonathan D, Zhou, Tian, Zhang, Kai, Zheng, Xue, Zhang, Yunyan, Zhang, Meng, Wu, Mingxuan, Wang, Hailong, Tao, Cheng, Singh, Balwinder, Rhoades, Alan M, Qin, Yi, Li, Hong-Yi, Feng, Yan, Zhang, Yuying, Zhang, Chengzhu, Zender, Charles S, Xie, Shaocheng, Roesler, Erika L, Roberts, Andrew F, Mametjanov, Azamat, Maltrud, Mathew E, Keen, Noel D, Jacob, Robert L, Jablonowski, Christiane, Hughes, Owen K, Forsyth, Ryan M, Di Vittorio, Alan V, Caldwell, Peter M, Bisht, Gautam, McCoy, Renata B, Leung, L Ruby, and Bader, David C

Subjects
Earth Sciences, Oceanography, Atmospheric Sciences, Climate Action, Earth sciences
Abstract

This paper provides an overview of the United States (US) Department of Energy's (DOE's) Energy Exascale Earth System Model version 2 (E3SMv2) fully coupled regionally refined model (RRM) and documents the overall atmosphere, land, and river results from the Coupled Model Intercomparison Project 6 (CMIP6) DECK (Diagnosis, Evaluation, and Characterization of Klima) and historical simulations - a first-of-its-kind set of climate production simulations using RRM. The North American (NA) RRM (NARRM) is developed as the high-resolution configuration of E3SMv2 with the primary goal of more explicitly addressing DOE's mission needs regarding impacts to the US energy sector facing Earth system changes. The NARRM features finer horizontal resolution grids centered over NA, consisting of 25→100¯km atmosphere and land, a 0.125 river-routing model, and 14→60¯km ocean and sea ice. By design, the computational cost of NARRM is 1/43× of the uniform low-resolution (LR) model at 100¯km but only 1/4¯10¯%-20¯% of a globally uniform high-resolution model at 25¯km. A novel hybrid time step strategy for the atmosphere is key for NARRM to achieve improved climate simulation fidelity within the high-resolution patch without sacrificing the overall global performance. The global climate, including climatology, time series, sensitivity, and feedback, is confirmed to be largely identical between NARRM and LR as quantified with typical climate metrics. Over the refined NA area, NARRM is generally superior to LR, including for precipitation and clouds over the contiguous US (CONUS), summertime marine stratocumulus clouds off the coast of California, liquid and ice phase clouds near the North Pole region, extratropical cyclones, and spatial variability in land hydrological processes. The improvements over land are related to the better-resolved topography in NARRM, whereas those over ocean are attributable to the improved air-sea interactions with finer grids for both atmosphere and ocean and sea ice. Some features appear insensitive to the resolution change analyzed here, for instance the diurnal propagation of organized mesoscale convective systems over CONUS and the warm-season land-atmosphere coupling at the southern Great Plains. In summary, our study presents a realistically efficient approach to leverage the fully coupled RRM framework for a standard Earth system model release and high-resolution climate production simulations.

Published
2023

10. A machine learning approach targeting parameter estimation for plant functional type coexistence modeling using ELM-FATES (v2.0)

Author

Li, Lingcheng, Fang, Yilin, Zheng, Zhonghua, Shi, Mingjie, Longo, Marcos, Koven, Charles D, Holm, Jennifer A, Fisher, Rosie A, McDowell, Nate G, Chambers, Jeffrey, and Leung, L Ruby

Subjects
Earth Sciences, Affordable and Clean Energy, Earth sciences
Abstract

Tropical forest dynamics play a crucial role in the global carbon, water, and energy cycles. However, realistically simulating the dynamics of competition and coexistence between different plant functional types (PFTs) in tropical forests remains a significant challenge. This study aims to improve the modeling of PFT coexistence in the Functionally Assembled Terrestrial Ecosystem Simulator (FATES), a vegetation demography model implemented in the Energy Exascale Earth System Model (E3SM) land model (ELM), ELM-FATES. Specifically, we explore (1) whether plant trait relationships established from field measurements can constrain ELM-FATES simulations and (2) whether machine learning (ML)-based surrogate models can emulate the complex ELM-FATES model and optimize parameter selections to improve PFT coexistence modeling. We conducted three ensembles of ELM-FATES experiments at a tropical forest site near Manaus, Brazil. By comparing the ensemble experiments without (Exp-CTR) and with (Exp-OBS) consideration of observed trait relationships, we found that accounting for these relationships slightly improves the simulations of water, energy, and carbon variables when compared to observations but degrades the simulation of PFT coexistence. Using ML-based surrogate models trained on Exp-CTR, we optimized the trait parameters in ELM-FATES and conducted another ensemble of experiments (Exp-ML) with these optimized parameters. The proportion of PFT coexistence experiments significantly increased from 21 % in Exp-CTR to 73 % in Exp-ML. After filtering the experiments that allow for PFT coexistence to agree with observations (within 15 % tolerance), 33 % of the Exp-ML experiments were retained, which is a significant improvement compared to the 1.4 % in Exp-CTR. Exp-ML also accurately reproduces the annual means and seasonal variations in water, energy, and carbon fluxes and the field inventory of aboveground biomass. This study represents a reproducible method that utilizes machine learning to identify parameter values that improve model fidelity against observations and PFT coexistence in vegetation demography models for diverse ecosystems. Our study also suggests the need for new mechanisms to enhance the robust simulation of coexisting plants in ELM-FATES and has significant implications for modeling the response and feedbacks of ecosystem dynamics to climate change.

Published
2023

11. The DOE E3SM Model Version 2: Overview of the Physical Model and Initial Model Evaluation

Author

Golaz, Jean‐Christophe, Van Roekel, Luke P, Zheng, Xue, Roberts, Andrew F, Wolfe, Jonathan D, Lin, Wuyin, Bradley, Andrew M, Tang, Qi, Maltrud, Mathew E, Forsyth, Ryan M, Zhang, Chengzhu, Zhou, Tian, Zhang, Kai, Zender, Charles S, Wu, Mingxuan, Wang, Hailong, Turner, Adrian K, Singh, Balwinder, Richter, Jadwiga H, Qin, Yi, Petersen, Mark R, Mametjanov, Azamat, Ma, Po‐Lun, Larson, Vincent E, Krishna, Jayesh, Keen, Noel D, Jeffery, Nicole, Hunke, Elizabeth C, Hannah, Walter M, Guba, Oksana, Griffin, Brian M, Feng, Yan, Engwirda, Darren, Di Vittorio, Alan V, Dang, Cheng, Conlon, LeAnn M, Chen, Chih‐Chieh‐Jack, Brunke, Michael A, Bisht, Gautam, Benedict, James J, Asay‐Davis, Xylar S, Zhang, Yuying, Zhang, Meng, Zeng, Xubin, Xie, Shaocheng, Wolfram, Phillip J, Vo, Tom, Veneziani, Milena, Tesfa, Teklu K, Sreepathi, Sarat, Salinger, Andrew G, Eyre, JE Jack Reeves, Prather, Michael J, Mahajan, Salil, Li, Qing, Jones, Philip W, Jacob, Robert L, Huebler, Gunther W, Huang, Xianglei, Hillman, Benjamin R, Harrop, Bryce E, Foucar, James G, Fang, Yilin, Comeau, Darin S, Caldwell, Peter M, Bartoletti, Tony, Balaguru, Karthik, Taylor, Mark A, McCoy, Renata B, Leung, L Ruby, and Bader, David C

Subjects
Climate Action, DOE E3SM, climate modeling, Atmospheric Sciences
Abstract

This work documents version two of the Department of Energy's Energy Exascale Earth System Model (E3SM). E3SMv2 is a significant evolution from its predecessor E3SMv1, resulting in a model that is nearly twice as fast and with a simulated climate that is improved in many metrics. We describe the physical climate model in its lower horizontal resolution configuration consisting of 110 km atmosphere, 165 km land, 0.5° river routing model, and an ocean and sea ice with mesh spacing varying between 60 km in the mid-latitudes and 30 km at the equator and poles. The model performance is evaluated with Coupled Model Intercomparison Project Phase 6 Diagnosis, Evaluation, and Characterization of Klima simulations augmented with historical simulations as well as simulations to evaluate impacts of different forcing agents. The simulated climate has many realistic features of the climate system, with notable improvements in clouds and precipitation compared to E3SMv1. E3SMv1 suffered from an excessively high equilibrium climate sensitivity (ECS) of 5.3 K. In E3SMv2, ECS is reduced to 4.0 K which is now within the plausible range based on a recent World Climate Research Program assessment. However, a number of important biases remain including a weak Atlantic Meridional Overturning Circulation, deficiencies in the characteristics and spectral distribution of tropical atmospheric variability, and a significant underestimation of the observed warming in the second half of the historical period. An analysis of single-forcing simulations indicates that correcting the historical temperature bias would require a substantial reduction in the magnitude of the aerosol-related forcing.

Published
2022

12. Metrics as tools for bridging climate science and applications

Author

Reed, Kevin A, Goldenson, Naomi, Grotjahn, Richard, Gutowski, William J, Jagannathan, Kripa, Jones, Andrew D, Leung, L Ruby, McGinnis, Seth A, Pryor, Sara C, Srivastava, Abhishekh K, Ullrich, Paul A, and Zarzycki, Colin M

Subjects
Climate Change Impacts and Adaptation, Information and Computing Sciences, Environmental Sciences, Behavioral and Social Science, Climate Action, climate change, climate model, co-production, metrics
Abstract

In climate science and applications, the term “metric” is used to describe the distillation of complex, multifaceted evaluations to summarize the overall quality of a model simulation, or other data product, and/or as a means to quantify some response to climate change. Metrics provide insights into the fidelity of processes and outcomes from climate models and can assist with both differentiating models' representation of variables or processes and informing whether models are “fit for purpose.” Metrics can also provide a valuable reference point for co-production of knowledge between climate scientists and climate impact practitioners. Although continued metric developments enable model developers to better understand the impacts of decisions made in the model design process, metrics also have implications for the characterization of uncertainty and facilitating analyses of underlying physical processes. As a result, comprehensive evaluation with multiple metrics enhances usability of climate information by both scientific and stakeholder communities. This paper presents examples of insights gained from the development and appropriate use of metrics, and provides examples of how metrics can be used to engage with stakeholders and inform decision-making. This article is categorized under: Climate Models and Modeling > Knowledge Generation with Models The Social Status of Climate Change Knowledge > Climate Science and Decision Making Assessing Impacts of Climate Change > Evaluating Future Impacts of Climate Change.

Published
2022

20. Exploratory Precipitation Metrics: Spatiotemporal Characteristics, Process-Oriented, and Phenomena-Based

Author

Leung, L Ruby, Boos, William R, Catto, Jennifer L, A. DeMott, Charlotte, Martin, Gill M, Neelin, J David, O’Brien, Travis A, Xie, Shaocheng, Feng, Zhe, Klingaman, Nicholas P, Kuo, Yi-Hung, Lee, Robert W, Martinez-Villalobos, Cristian, Vishnu, S, Priestley, Matthew DK, Tao, Cheng, and Zhou, Yang

Subjects
Earth Sciences, Atmospheric Sciences, Bioengineering, Climate Action, Precipitation, Climate models, Diagnostics, Model evaluation, performance, Oceanography, Geomatic Engineering, Meteorology & Atmospheric Sciences, Atmospheric sciences, Climate change science
Abstract

Precipitation sustains life and supports human activities, making its prediction one of the most societally relevant challenges in weather and climate modeling. Limitations in modeling precipitation underscore the need for diagnostics and metrics to evaluate precipitation in simulations and predictions. While routine use of basic metrics is important for documenting model skill, more sophisticated diagnostics and metrics aimed at connecting model biases to their sources and revealing precipitation characteristics relevant to how model precipitation is used are critical for improving models and their uses. This paper illustrates examples of exploratory diagnostics and metrics including 1) spatiotemporal characteristics metrics such as diurnal variability, probability of extremes, duration of dry spells, spectral characteristics, and spatiotemporal coherence of precipitation; 2) process-oriented metrics based on the rainfall–moisture coupling and temperature–water vapor environments of precipitation; and 3) phenomena-based metrics focusing on precipitation associated with weather phenomena including low pressure systems, mesoscale convective systems, frontal systems, and atmospheric rivers. Together, these diagnostics and metrics delineate the multifaceted and multiscale nature of precipitation, its relations with the environments, and its generation mechanisms. The metrics are applied to historical simulations from phases 5 and 6 of the Coupled Model Intercomparison Project. Models exhibit diverse skill as measured by the suite of metrics, with very few models consistently ranked as top or bottom performers compared to other models in multiple metrics. Analysis of model skill across metrics and models suggests possible relationships among subsets of metrics, motivating the need for more systematic analysis to understand model biases for informing model development.

Published
2022

21. Diurnal Rainfall Response to the Physiological and Radiative Effects of CO2 in Tropical Forests in the Energy Exascale Earth System Model v1

Author

Harrop, Bryce E, Burrows, Susannah M, Calvin, Katherine, Kooperman, Gabriel J, Leung, L Ruby, Maltrud, Mathew E, Shi, Xiaoying, Tang, Jinyun, Tang, Qi, Wang, Hailong, and Zhu, Qing

Subjects
Climate Action, tropics, precipitation, diurnal cycle, biogeochemistry, Atmospheric Sciences, Physical Geography and Environmental Geoscience
Abstract

Understanding how the connection between rainfall and tropical forests will respond to increasing CO2 concentrations is a key element in understanding how the tropical water cycle will respond to increasing CO2. The plant physiological and radiative impacts of CO2 on rainfall patterns over tropical forest regions are examined in the Energy Exascale Earth System Model version 1.1 (E3SMv1.1-BGC) biogeochemistry experiments. Composite analysis reveals a dampening of the diurnal cycle of rainfall over the Amazon, Congo, and Maritime Continent in response to rising CO2 levels, regardless of the sign of total rainfall change. A full factorial model experiment confirms that the CO2 radiative and CO2 plant physiological effects can individually or jointly reduce the magnitude of the rainfall diurnal cycle, though the physical pathway giving rise to the reduction differs between the two effects. For the physiological response, stomatal closure reduces evapotranspiration, which dries the boundary layer and raises the lifting condensation level. These effects combine to reduce deep convective rainfall during its peak occurrence in the late daytime to early nighttime period. For the radiative response, a relative reduction in daytime Convective Available Potential Energy (consistent with a reduction in the diurnal temperature range) leads to less frequent triggering of deep convection and a reduction of rainfall diurnal amplitude. These diurnal rainfall changes are structurally similar across seasons, and show little sensitivity to representation of nutrient coupling for the land biogeochemistry. In agreement with previous findings, the physiological response has only minor impact on extreme rainfall relative to the radiative response.

Published
2022

23. Trends in surface equivalent potential temperature: A more comprehensive metric for global warming and weather extremes

Author

Song, Fengfei, Zhang, Guang J, Ramanathan, V, and Leung, L Ruby

Subjects
Climate Action, global warming, surface equivalent potential temperature, atmospheric convection, weather extremes
Abstract

Trends in surface air temperature (SAT) are a common metric for global warming. Using observations and observationally driven models, we show that a more comprehensive metric for global warming and weather extremes is the trend in surface equivalent potential temperature (Thetae_sfc) since it also accounts for the increase in atmospheric humidity and latent energy. From 1980 to 2019, while SAT increased by 0.79[Formula: see text], Thetae_sfc increased by 1.48[Formula: see text] globally and as much as 4[Formula: see text] in the tropics. The increase in water vapor is responsible for the factor of 2 difference between SAT and Thetae_sfc trends. Thetae_sfc increased more uniformly (than SAT) between the midlatitudes of the southern hemisphere and the northern hemisphere, revealing the global nature of the heating added by greenhouse gases (GHGs). Trends in heat extremes and extreme precipitation are correlated strongly with the global/tropical trends in Thetae_sfc. The tropical amplification of Thetae_sfc is as large as the arctic amplification of SAT, accounting for the observed global positive trends in deep convection and a 20% increase in heat extremes. With unchecked GHG emissions, while SAT warming can reach 4.8[Formula: see text] by 2100, the global mean Thetae_sfc can increase by as much as 12[Formula: see text], with corresponding increases of 12[Formula: see text] (median) to 24[Formula: see text] (5% of grid points) in land surface temperature extremes, a 14- to 30-fold increase in frequency of heat extremes, a 40% increase in the energy available for tropical deep convection, and an up to 60% increase in extreme precipitation.

Published
2022

24. Impact of the numerical solution approach of a plant hydrodynamic model (v0.1) on vegetation dynamics

Author

Fang, Yilin, Leung, L Ruby, Knox, Ryan, Koven, Charlie, and Bond-Lamberty, Ben

Subjects
Earth Sciences, Earth sciences
Abstract

Numerous plant hydrodynamic models have started to be implemented in vegetation dynamics models, reflecting the central role of plant hydraulic traits in driving water, energy, and carbon cycles, as well as plant adaptation to climate change. Different numerical approximations of the governing equations of the hydrodynamic models have been documented, but the numerical accuracy of these models and its subsequent effects on the simulated vegetation function and dynamics have rarely been evaluated. Using different numerical solution methods (including implicit and explicit approaches) and vertical discrete grid resolutions, we evaluated the numerical performance of a plant hydrodynamic module in the Functionally Assembled Terrestrial Ecosystem Simulator (FATES-HYDRO version 0.1) based on single-point and global simulations. Our simulation results showed that when near-surface vertical grid spacing is coarsened (grid size >10 cm), the model significantly overestimates aboveground biomass (AGB) in most of the temperate forest locations and underestimates AGB in the boreal forest locations, as compared to a simulation with finer vertical grid spacing. Grid coarsening has a small effect on AGB in the tropical zones of Asia and South America. In particular, coarse surface grid resolution should not be used when there are large and prolonged water content differences among soil layers at depths due to long dry-season duration and/or well-drained soil or when soil evaporation is a dominant fraction of evapotranspiration. Similarly, coarse surface grid resolution should not be used when there is lithologic discontinuity along the soil depth. This information is useful for uncertainty quantification, sensitivity analysis, or the training of surrogate models to design the simulations when computational cost limits the use of ensemble simulations.

Published
2022

25. Atmospheric river representation in the Energy Exascale Earth System Model (E3SM) version 1.0

Author

Kim, Sol, Leung, L Ruby, Guan, Bin, and Chiang, John CH

Subjects
Climate Action, Earth Sciences
Abstract

The Energy Exascale Earth System Model (E3SM) project is an ongoing, state-of-the-science Earth system modeling, simulation, and prediction project developed by the US Department of Energy (DOE). With an emphasis on supporting the DOE's energy mission, understanding and quantifying how well the model simulates water cycle processes is of particular importance. Here, we evaluate E3SM version 1.0 (v1.0) for its ability to represent atmospheric rivers (ARs), which play significant roles in water vapor transport and precipitation. The characteristics and precipitation associated with global ARs in E3SM at standard resolution (1×1) are compared to the Modern-Era Retrospective analysis for Research and Applications, version 2 (MERRA2). Global patterns of AR frequencies in E3SM show high degrees of correlation (≥0.97) with MERRA2 and low mean absolute errors (MAEs;

Published
2022

26. Modeling the Joint Effects of Vegetation Characteristics and Soil Properties on Ecosystem Dynamics in a Panama Tropical Forest

Author

Cheng, Yanyan, Leung, L Ruby, Huang, Maoyi, Koven, Charles, Detto, Matteo, Knox, Ryan, Bisht, Gautam, Bretfeld, Mario, and Fisher, Rosie A

Subjects
Earth Sciences, Atmospheric Sciences, Geoinformatics, Life on Land, tropical forest, coexistence, vegetation demographic model, Earth system model, E3SM-FATES, soil properties, Atmospheric sciences
Abstract

In tropical forests, both vegetation characteristics and soil properties are important not only for controlling energy, water, and gas exchanges directly but also determining the competition among species, successional dynamics, forest structure and composition. However, the joint effects of the two factors have received limited attention in Earth system model development. Here we use a vegetation demographic model, the Functionally Assembled Terrestrial Ecosystem Simulator (FATES) implemented in the Energy Exascale Earth System Model (E3SM) Land Model (ELM), ELM-FATES, to explore how plant traits and soil properties affect tropical forest growth and composition concurrently. A large ensemble of simulations with perturbed vegetation and soil hydrological parameters is conducted at the Barro Colorado Island, Panama. The simulations are compared against observed carbon, energy, and water fluxes. We find that soil hydrological parameters, particularly the scaling exponent of the soil retention curve (Bsw), play crucial roles in controlling forest diversity, with higher Bsw values (>7) favoring late successional species in competition, and lower Bsw values (1 ∼ 7) promoting the coexistence of early and late successional plants. Considering the additional impact of soil properties resolves a systematic bias of FATES in simulating sensible/latent heat partitioning with repercussion on water budget and plant coexistence. A greater fraction of deeper tree roots can help maintain the dry-season soil moisture and plant gas exchange. As soil properties are as important as vegetation parameters in predicting tropical forest dynamics, more efforts are needed to improve parameterizations of soil functions and belowground processes and their interactions with aboveground vegetation dynamics.

Published
2022

29. Tibetan Plateau Snow Cover: Future Snowpack Loss and Connections to Extreme Events

Author

Leung, L. Ruby

Subjects
Tibetan Plateau -- Environmental aspects -- Natural history, Extreme weather -- Environmental aspects, Snow -- Environmental aspects -- Forecasts and trends, Market trend/market analysis, Business, Earth sciences
Abstract

Through orographic forcing, mountains effectively harness water vapor into freshwater in the form of precipitation, a large fraction of which is stored in mountain snowpack during winter and released as [...]

Published
2024

30. Disentangling the Effects of Vapor Pressure Deficit and Soil Water Availability on Canopy Conductance in a Seasonal Tropical Forest During the 2015 El Niño Drought

Author

Fang, Yilin, Leung, L Ruby, Wolfe, Brett T, Detto, Matteo, Knox, Ryan G, McDowell, Nate G, Grossiord, Charlotte, Xu, Chonggang, Christoffersen, Bradley O, Gentine, Pierre, Koven, Charles D, and Chambers, Jeffrey Q

Subjects
Earth Sciences, Atmospheric Sciences, Climate Change Science, Clean Water and Sanitation, canopy conductance limitation, ELM, plant hydrodynamic model HYDRO, tropical forest, vapor pressure deficit, water stress, Physical Geography and Environmental Geoscience, Atmospheric sciences, Climate change science
Abstract

Water deficit in the atmosphere and soil are two key interactive factors that constrain transpiration and vegetation productivity. It is not clear which of these two factors is more important for the water and carbon flux response to drought stress in ecosystems. In this study, field data and numerical modeling were used to isolate their impact on evapotranspiration (ET) and gross primary productivity (GPP) at a tropical forest site in Barro Colorado Island (BCI), Panama, focusing on their response to the drought induced by the El Niño event of 2015–2016. Numerical simulations were performed using a plant hydrodynamic scheme (HYDRO) and a heuristic approach that ignores stomatal sensitivity to leaf water potential in the Energy Exascale Earth System Model (E3SM) Land Model (ELM). The sensitivity of canopy conductance (Gs) to vapor pressure deficit (VPD) obtained from eddy-covariance fluxes and measured sap flux shows that, at both ecosystem and plant scale, soil water stress is more important in limiting Gs than VPD at BCI during the El Niño event. The model simulations confirmed the importance of water stress limitation on Gs, but overestimated the VPD impact on Gs compared to that estimated from the observations. We also found that the predicted soil moisture is less sensitive to the diversity of plant hydraulic traits than ET and GPP. During the dry season at BCI, seasonal ET, especially soil evaporation at VPD > 0.42 kPa, simulated using HYDRO and ELM, were too strong and will require alternative parameterizations.

Published
2021

31. Increased extreme rains intensify erosional nitrogen and phosphorus fluxes to the northern Gulf of Mexico in recent decades

Author

Tan, Zeli, Leung, L Ruby, Li, Hong-Yi, Tesfa, Teklu, Zhu, Qing, Yang, Xiaojuan, Liu, Ying, and Huang, Maoyi

Subjects
soil erosion, particulate phosphorus, particulate nitrogen, eutrophication, the northern Gulf of Mexico, extreme rainfall, Meteorology & Atmospheric Sciences
Abstract

Soil erosion delivers enormous amounts of macro-nutrients including nitrogen (N) and phosphorus (P) from land to rivers, potentially sustaining water column bioavailable nutrient levels for decades. In this study, we represent erosional N and P fluxes in the Energy Exascale Earth System Model (E3SM) and apply the model to the continental United States. We estimate that during 1991-2019 soil erosion delivers 775 Gg yr-1 (1 Gg = 109 g) of particulate N (PN) and 328 Gg yr-1 of particulate P (PP) on average to the drainage basins of the northern Gulf of Mexico, including the Mississippi/Atchafalaya River and other rivers draining to the Texas Gulf and the Eastern Gulf. Our model simulation shows that in these rivers PP is the dominant P constituent and over 55% of P exported by erosion comes from soil P pools that could become bioavailable within decades. More importantly, we find that during 1991-2019 erosional N and P fluxes increase at rates of about 15 Gg N yr-1 and 6 Gg P yr-1, respectively, due to increased extreme rains in the Mississippi/Atchafalaya river basin, and this intensification of erosional N and P fluxes drive the significant increase of riverine PN and PP yields to the northern Gulf of Mexico. With extreme rains projected to increase with warming, erosional nutrient fluxes in the region would likely continue to rise in the future, thus complicating the effort of reducing eutrophication in the inland and coastal waters.

Published
2021

40. Supplementary material to "Evaluation of global fire simulations in CMIP6 Earth system models"

Author

Li, Fang, primary, Song, Xiang, additional, Harrison, Sandy P., additional, Marlon, Jennifer R., additional, Lin, Zhongda, additional, Leung, L. Ruby, additional, Schwinger, Jörg, additional, Marécal, Virginie, additional, Wang, Shiyu, additional, Ward, Daniel S., additional, Dong, Xiao, additional, Lee, Hanna, additional, Nieradzik, Lars, additional, Rabin, Sam S., additional, and Séférian, Roland, additional

Published
2024
Full Text
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41. Evaluation of global fire simulations in CMIP6 Earth system models

Author

Li, Fang, primary, Song, Xiang, additional, Harrison, Sandy P., additional, Marlon, Jennifer R., additional, Lin, Zhongda, additional, Leung, L. Ruby, additional, Schwinger, Jörg, additional, Marécal, Virginie, additional, Wang, Shiyu, additional, Ward, Daniel S., additional, Dong, Xiao, additional, Lee, Hanna, additional, Nieradzik, Lars, additional, Rabin, Sam S., additional, and Séférian, Roland, additional

Published
2024
Full Text
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42. Increases in Future AR Count and Size: Overview of the ARTMIP Tier 2 CMIP5/6 Experiment

Author

O'Brien, Travis Allen, Wehner, Michael F, Payne, Ashley E, Shields, Christine A, Rutz, Jonathan J, Leung, L Ruby, Ralph, F Martin, Marquardt Collow, Allison B, Guan, Bin, Lora, Juan Manuel, McClenny, Elizabeth, Nardi, Kyle M, Ramos, Alexandre M, Tomé, Ricardo, Sarangi, Chandan, Shearer, Eric Jay, Ullrich, Paul, Zarzycki, Colin M, Loring, Burlen, Huang, Huanping, Inda Díaz, Héctor Alejandro, Rhoades, Alan M, and Zhou, Yang

Published
2020

43. Enhanced Predictability of Eastern North Pacific Tropical Cyclone Activity Using the ENSO Longitude Index

Author

Balaguru, Karthik, Patricola, Christina M, Hagos, Samson M, Leung, L Ruby, and Dong, Lu

Subjects
Oceanography, Earth Sciences, Atmospheric Sciences, Climate Change Science, Geophysics, tropical cyclones, ENSO, ocean heat content, climate variability, Meteorology & Atmospheric Sciences
Abstract

While El Niño–Southern Oscillation (ENSO) influences eastern North Pacific (ENP) tropical cyclones (TCs) through a variety of atmospheric processes when examined concurrently, ocean pathways dominate at longer lead times. The eastward displacement of the warm pool during an El Niño, which carries warm water into the ENP basin, is the primary oceanic mechanism. Despite this, the question of whether an accurate knowledge of preseason ENSO conditions enhances predictability of ENP TCs has not been addressed specifically. In this study, we show that relative to traditional indices of ENSO, the ENSO Longitude Index (ELI) captures changes in the location of deep convection and associated thermocline processes more accurately. Consequently, the ELI explains more variability in the upper-ocean heat content, and thus TC activity, at lead times of several months in the ENP basin. These results motivate the need to further explore the predictability of ENP TCs associated with ENSO.

Published
2020

45. The pantropical response of soil moisture to El Niño

Author

Solander, Kurt C, Newman, Brent D, de Araujo, Alessandro Carioca, Barnard, Holly R, Berry, Z Carter, Bonal, Damien, Bretfeld, Mario, Burban, Benoit, Candido, Luiz Antonio, Célleri, Rolando, Chambers, Jeffery Q, Christoffersen, Bradley O, Detto, Matteo, Dorigo, Wouter A, Ewers, Brent E, Ferreira, Savio José Filgueiras, Knohl, Alexander, Leung, L Ruby, McDowell, Nate G, Miller, Gretchen R, Monteiro, Maria Terezinha Ferreira, Moore, Georgianne W, Negron-Juarez, Robinson, Saleska, Scott R, Stiegler, Christian, Tomasella, Javier, and Xu, Chonggang

Subjects
Earth Sciences, Oceanography, Climate Action, Physical Geography and Environmental Geoscience, Civil Engineering, Environmental Engineering, Hydrology, Physical geography and environmental geoscience, Geomatic engineering
Abstract

The 2015-2016 El Niño event ranks as one of the most severe on record in terms of the magnitude and extent of sea surface temperature (SST) anomalies generated in the tropical Pacific Ocean. Corresponding global impacts on the climate were expected to rival, or even surpass, those of the 1997-1998 severe El Niño event, which had SST anomalies that were similar in size. However, the 2015-2016 event failed to meet expectations for hydrologic change in many areas, including those expected to receive well above normal precipitation. To better understand how climate anomalies during an El Niño event impact soil moisture, we investigate changes in soil moisture in the humid tropics (between ±25ĝˆ ) during the three most recent super El Niño events of 1982-1983, 1997-1998 and 2015-2016, using data from the Global Land Data Assimilation System (GLDAS). First, we use in situ soil moisture observations obtained from 16 sites across five continents to validate and bias-correct estimates from GLDAS (r2Combining double low line0.54). Next, we apply a k-means cluster analysis to the soil moisture estimates during the El Niño mature phase, resulting in four groups of clustered data. The strongest and most consistent decreases in soil moisture occur in the Amazon basin and maritime southeastern Asia, while the most consistent increases occur over eastern Africa. In addition, we compare changes in soil moisture to both precipitation and evapotranspiration, which showed a lack of agreement in the direction of change between these variables and soil moisture most prominently in the southern Amazon basin, the Sahel and mainland southeastern Asia. Our results can be used to improve estimates of spatiotemporal differences in El Niño impacts on soil moisture in tropical hydrology and ecosystem models at multiple scales..

Published
2020

46. The Atmospheric River Tracking Method Intercomparison Project (ARTMIP): Quantifying Uncertainties in Atmospheric River Climatology

Author

Rutz, Jonathan J, Shields, Christine A, Lora, Juan M, Payne, Ashley E, Guan, Bin, Ullrich, Paul, O’Brien, Travis, Leung, L Ruby, Ralph, F Martin, Wehner, Michael, Brands, Swen, Collow, Allison, Goldenson, Naomi, Gorodetskaya, Irina, Griffith, Helen, Kashinath, Karthik, Kawzenuk, Brian, Krishnan, Harinarayan, Kurlin, Vitaliy, Lavers, David, Magnusdottir, Gudrun, Mahoney, Kelly, McClenny, Elizabeth, Muszynski, Grzegorz, Nguyen, Phu Dinh, Prabhat, Mr, Qian, Yun, Ramos, Alexandre M, Sarangi, Chandan, Sellars, Scott, Shulgina, T, Tome, Ricardo, Waliser, Duane, Walton, Daniel, Wick, Gary, Wilson, Anna M, and Viale, Maximiliano

Subjects
Climate Action, Atmospheric Sciences, Physical Geography and Environmental Geoscience
Abstract

Atmospheric rivers (ARs) are now widely known for their association with high-impact weather events and long-term water supply in many regions. Researchers within the scientific community have developed numerous methods to identify and track of ARs—a necessary step for analyses on gridded data sets, and objective attribution of impacts to ARs. These different methods have been developed to answer specific research questions and hence use different criteria (e.g., geometry, threshold values of key variables, and time dependence). Furthermore, these methods are often employed using different reanalysis data sets, time periods, and regions of interest. The goal of the Atmospheric River Tracking Method Intercomparison Project (ARTMIP) is to understand and quantify uncertainties in AR science that arise due to differences in these methods. This paper presents results for key AR-related metrics based on 20+ different AR identification and tracking methods applied to Modern-Era Retrospective Analysis for Research and Applications Version 2 reanalysis data from January 1980 through June 2017. We show that AR frequency, duration, and seasonality exhibit a wide range of results, while the meridional distribution of these metrics along selected coastal (but not interior) transects are quite similar across methods. Furthermore, methods are grouped into criteria-based clusters, within which the range of results is reduced. AR case studies and an evaluation of individual method deviation from an all-method mean highlight advantages/disadvantages of certain approaches. For example, methods with less (more) restrictive criteria identify more (less) ARs and AR-related impacts. Finally, this paper concludes with a discussion and recommendations for those conducting AR-related research to consider.

Published
2019

47. The Community Land Model Version 5: Description of New Features, Benchmarking, and Impact of Forcing Uncertainty

Author

Lawrence, David M, Fisher, Rosie A, Koven, Charles D, Oleson, Keith W, Swenson, Sean C, Bonan, Gordon, Collier, Nathan, Ghimire, Bardan, van Kampenhout, Leo, Kennedy, Daniel, Kluzek, Erik, Lawrence, Peter J, Li, Fang, Li, Hongyi, Lombardozzi, Danica, Riley, William J, Sacks, William J, Shi, Mingjie, Vertenstein, Mariana, Wieder, William R, Xu, Chonggang, Ali, Ashehad A, Badger, Andrew M, Bisht, Gautam, van den Broeke, Michiel, Brunke, Michael A, Burns, Sean P, Buzan, Jonathan, Clark, Martyn, Craig, Anthony, Dahlin, Kyla, Drewniak, Beth, Fisher, Joshua B, Flanner, Mark, Fox, Andrew M, Gentine, Pierre, Hoffman, Forrest, Keppel‐Aleks, Gretchen, Knox, Ryan, Kumar, Sanjiv, Lenaerts, Jan, Leung, L Ruby, Lipscomb, William H, Lu, Yaqiong, Pandey, Ashutosh, Pelletier, Jon D, Perket, Justin, Randerson, James T, Ricciuto, Daniel M, Sanderson, Benjamin M, Slater, Andrew, Subin, Zachary M, Tang, Jinyun, Thomas, R Quinn, Martin, Maria Val, and Zeng, Xubin

Subjects
Earth Sciences, Atmospheric Sciences, Geoinformatics, Climate Action, global land model, Earth System Modeling, carbon and nitrogen cycling, hydrology, benchmarking, Atmospheric sciences
Abstract

The Community Land Model (CLM) is the land component of the Community Earth System Model (CESM) and is used in several global and regional modeling systems. In this paper, we introduce model developments included in CLM version 5 (CLM5), which is the default land component for CESM2. We assess an ensemble of simulations, including prescribed and prognostic vegetation state, multiple forcing data sets, and CLM4, CLM4.5, and CLM5, against a range of metrics including from the International Land Model Benchmarking (ILAMBv2) package. CLM5 includes new and updated processes and parameterizations: (1) dynamic land units, (2) updated parameterizations and structure for hydrology and snow (spatially explicit soil depth, dry surface layer, revised groundwater scheme, revised canopy interception and canopy snow processes, updated fresh snow density, simple firn model, and Model for Scale Adaptive River Transport), (3) plant hydraulics and hydraulic redistribution, (4) revised nitrogen cycling (flexible leaf stoichiometry, leaf N optimization for photosynthesis, and carbon costs for plant nitrogen uptake), (5) global crop model with six crop types and time-evolving irrigated areas and fertilization rates, (6) updated urban building energy, (7) carbon isotopes, and (8) updated stomatal physiology. New optional features include demographically structured dynamic vegetation model (Functionally Assembled Terrestrial Ecosystem Simulator), ozone damage to plants, and fire trace gas emissions coupling to the atmosphere. Conclusive establishment of improvement or degradation of individual variables or metrics is challenged by forcing uncertainty, parametric uncertainty, and model structural complexity, but the multivariate metrics presented here suggest a general broad improvement from CLM4 to CLM5.

Published
2019

48. The DOE E3SM Coupled Model Version 1: Description and Results at High Resolution

Author

Caldwell, Peter M, Mametjanov, Azamat, Tang, Qi, Van Roekel, Luke P, Golaz, Jean‐Christophe, Lin, Wuyin, Bader, David C, Keen, Noel D, Feng, Yan, Jacob, Robert, Maltrud, Mathew E, Roberts, Andrew F, Taylor, Mark A, Veneziani, Milena, Wang, Hailong, Wolfe, Jonathan D, Balaguru, Karthik, Cameron‐Smith, Philip, Dong, Lu, Klein, Stephen A, Leung, L Ruby, Li, Hong‐Yi, Li, Qing, Liu, Xiaohong, Neale, Richard B, Pinheiro, Marielle, Qian, Yun, Ullrich, Paul A, Xie, Shaocheng, Yang, Yang, Zhang, Yuying, Zhang, Kai, and Zhou, Tian

Subjects
Earth Sciences, Oceanography, Atmospheric Sciences, Climate Action, Atmospheric sciences, Geoinformatics
Abstract

This study provides an overview of the coupled high-resolution Version 1 of the Energy Exascale Earth System Model (E3SMv1) and documents the characteristics of a 50-year-long high-resolution control simulation with time-invariant 1950 forcings following the HighResMIP protocol. In terms of global root-mean-squared error metrics, this high-resolution simulation is generally superior to results from the low-resolution configuration of E3SMv1 (due to resolution, tuning changes, and possibly initialization procedure) and compares favorably to models in the CMIP5 ensemble. Ocean and sea ice simulation is particularly improved, due to better resolution of bathymetry, the ability to capture more variability and extremes in winds and currents, and the ability to resolve mesoscale ocean eddies. The largest improvement in this regard is an ice-free Labrador Sea, which is a major problem at low resolution. Interestingly, several features found to improve with resolution in previous studies are insensitive to resolution or even degrade in E3SMv1. Most notable in this regard are warm bias and associated stratocumulus deficiency in eastern subtropical oceans and lack of improvement in El Niño. Another major finding of this study is that resolution increase had negligible impact on climate sensitivity (measured by net feedback determined through uniform +4K prescribed sea surface temperature increase) and aerosol sensitivity. Cloud response to resolution increase consisted of very minor decrease at all levels. Large-scale patterns of precipitation bias were also relatively unaffected by grid spacing.

Published
2019

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