Your search keyword '"Kauffman, Brian"' showing total 4 results

1. The Benguela Upwelling System : Quantifying the Sensitivity to Resolution and Coastal Wind Representation in a Global Climate Model

Author

Small, R. Justin, Curchitser, Enrique, Hedstrom, Katherine, Kauffman, Brian, and Large, William G.

Published

2015

2. Subseasonal Earth System Prediction with CESM2.

Author

Richter, Jadwiga H., Glanville, Anne A., Edwards, James, Kauffman, Brian, Davis, Nicholas A., Jaye, Abigail, Kim, Hyemi, Pedatella, Nicholas M., Sun, Lantao, Berner, Judith, Kim, Who M., Yeager, Stephen G., Danabasoglu, Gokhan, Caron, Julie M., and Oleson, Keith W.

Subjects

NORTH Atlantic oscillation, ATMOSPHERIC models, MADDEN-Julian oscillation, STRATOSPHERIC chemistry, EARTH (Planet), TROPOSPHERIC chemistry, SEA ice

Abstract

Prediction systems to enable Earth system predictability research on the subseasonal time scale have been developed with the Community Earth System Model, version 2 (CESM2) using two configurations that differ in their atmospheric components. One system uses the Community Atmosphere Model, version 6 (CAM6) with its top near 40 km, referred to as CESM2(CAM6). The other employs the Whole Atmosphere Community Climate Model, version 6 (WACCM6) whose top extends to ∼140 km, and it includes fully interactive tropospheric and stratospheric chemistry [CESM2(WACCM6)]. Both systems are utilized to carry out subseasonal reforecasts for the 1999–2020 period following the Subseasonal Experiment's (SubX) protocol. Subseasonal prediction skill from both systems is compared to those of the National Oceanic and Atmospheric Administration CFSv2 and European Centre for Medium-Range Weather Forecasts (ECMWF) operational models. CESM2(CAM6) and CESM2(WACCM6) show very similar subseasonal prediction skill of 2-m temperature, precipitation, the Madden–Julian oscillation, and North Atlantic Oscillation to its previous version and to the NOAA CFSv2 model. Overall, skill of CESM2(CAM6) and CESM2(WACCM6) is a little lower than that of the ECMWF system. In addition to typical output provided by subseasonal prediction systems, CESM2 reforecasts provide comprehensive datasets for predictability research of multiple Earth system components, including three-dimensional output for many variables, and output specific to the mesosphere and lower-thermosphere (MLT) region from CESM2(WACCM6). It is shown that sudden stratosphere warming events, and the associated variability in the MLT, can be predicted ∼10 days in advance. Weekly real-time forecasts and reforecasts with CESM2(CAM6) and CESM2(WACCM6) are freely available. Significance Statement: We describe here the design and prediction skill of two subseasonal prediction systems based on two configurations of the Community Earth System Model, version 2 (CESM2): CESM2 with the Community Atmosphere Model, version 6 [CESM2(CAM6)] and CESM 2 with Whole Atmosphere Community Climate Model, version 6 [CESM2(WACCM6)] as its atmospheric component. These two systems provide a foundation for community-model based subseasonal prediction research. The CESM2(WACCM6) system provides a novel capability to explore the predictability of the stratosphere, mesosphere, and lower thermosphere. Both CESM2(CAM6) and CESM2(WACCM6) demonstrate subseasonal surface prediction skill comparable to that of the NOAA CFSv2 model, and a little lower than that of the ECMWF forecasting system. CESM2 reforecasts provide a comprehensive dataset for predictability research of multiple aspects of the Earth system, including the whole atmosphere up to 140 km, land, and sea ice. Weekly real-time forecasts, reforecasts, and models are publicly available. [ABSTRACT FROM AUTHOR]

Published

2022

3. Introducing the New Regional Community Earth System Model, R-CESM.

Author

Fu, Dan, Small, Justin, Kurian, Jaison, Liu, Yun, Kauffman, Brian, Gopal, Abishek, Ramachandran, Sanjiv, Shang, Zhi, Chang, Ping, Danabasoglu, Gokhan, Thayer-Calder, Katherine, Vertenstein, Mariana, Ma, Xiaohui, Yao, Hengkai, Li, Mingkui, Xu, Zhao, Lin, Xiaopei, Zhang, Shaoqing, and Wu, Lixin

Subjects

DOWNSCALING (Climatology), TROPICAL cyclones, WEATHER forecasting, OCEAN-atmosphere interaction, METEOROLOGICAL research, ATMOSPHERIC models

Abstract

The development of high-resolution, fully coupled, regional Earth system model systems is important for improving our understanding of climate variability, future projections, and extreme events at regional scales. Here we introduce and present an overview of the newly developed Regional Community Earth System Model (R-CESM). Different from other existing regional climate models, R-CESM is based on the Community Earth System Model version 2 (CESM2) framework. We have incorporated the Weather Research and Forecasting (WRF) Model and Regional Ocean Modeling System (ROMS) into CESM2 as additional components. As such, R-CESM can be conveniently used as a regional dynamical downscaling tool for the global CESM solutions or/and as a standalone high-resolution regional coupled model. The user interface of R-CESM follows that of CESM, making it readily accessible to the broader community. Among countless potential applications of R-CESM, we showcase here a few preliminary studies that illustrate its novel aspects and value. These include 1) assessing the skill of R-CESM in a multiyear, high-resolution, regional coupled simulation of the Gulf of Mexico; 2) examining the impact of WRF and CESM ocean–atmosphere coupling physics on tropical cyclone simulations; and 3) a convection-permitting simulation of submesoscale ocean–atmosphere interactions. We also discuss capabilities under development such as (i) regional refinement using a high-resolution ROMS nested within global CESM and (ii) "online" coupled data assimilation. Our open-source framework (publicly available at https://github.com/ihesp/rcesm1) can be easily adapted to a broad range of applications that are of interest to the users of CESM, WRF, and ROMS. [ABSTRACT FROM AUTHOR]

Published

2021

4. CPL6: THE NEW EXTENSIBLE, HIGH PERFORMANCE PARALLEL COUPLER FOR THE COMMUNITY CLIMATE SYSTEM MODEL.

Author

Craig, Anthony P., Jacob, Robert, Kauffman, Brian, Bettge, Tom, Larson, Jay, Ong, Everest, Ding, Chris, and Yun He

Subjects

HIGH performance computing, CLIMATOLOGY, ATMOSPHERIC models, MULTIPROCESSORS, COMPUTERS, INFORMATION technology

Abstract

The article focuses on cpl6 which is high performance parallel coupler for the community climate system model (CCSM). Like many climate models, CCSM is not developed from scratch as a single application but is instead a coupled application where each component is a highly complex application developed separately with its own coding style and data types. The uncoupled, or standalone, versions have their own user bases and scientific application areas and may be developed at multiple institutions. To couple models developed separately into a single application, CCSM has developed, over the past ten years, a framework that permits coupling with minimum modification to component models. This framework takes advantage of the fact that most component models need external surface forcing data. An aspect of the CCSM architecture is its multiple executable run-time system. Each component model is a separate binary program that executes concurrently on disjoint sets of hardware processors. Each component is run on multiple processors using the Message Passing Interface.

Published

2005