Weekly Seminar Format
Available via Zoom only. Contact the department to subscribe to the email list (zoom link provided in announcement).
Abstract
The NOAA Global Systems Laboratory’s (GSL’s) Grand Challenge is to deliver actionable global storm-scale prediction and environmental information through advanced technologies to serve society. Meeting the prediction aspect of our Grand Challenge requires a robust modeling system, including the dynamical core to solve the primitive equations on a defined grid, physics parameterizations to mimic small-scale and/or computationally expensive physical processes, and data assimilation to provide a reliable representation of the initial atmospheric state.
NOAA’s operational thunderstorm-scale to subseasonal-to-seasonal scale modeling activities rely on the Finite Volume on the Cubed Sphere, or FV3, dynamical core at the foundation of the Unified Forecast System (UFS). However, years of development have demonstrated that the FV3 dynamical core suffers from significant positive biases in thunderstorm updraft intensity, thunderstorm counts, and precipitation on thunderstorm-resolving scales. Consequently, GSL has adopted an alternative model and dynamical core, the Model for Prediction Across Scales-Atmosphere (MPAS-Atmosphere), as the foundation for its storm-scale model development activities.
As one of its initial steps toward meeting its Grand Challenge, GSL has been running twice-daily real-time MPAS-Atmosphere forecasts over the North Atlantic Basin as part of NOAA’s 2024 Hurricane Forecast Improvement Project. The associated hurricane track forecasts are highly skillful for all storms, with mean absolute errors of comparable magnitude to those from the National Hurricane Center’s official forecasts and NOAA’s Hurricane Analysis and Forecast System forecasts. Hurricane intensity errors are also highly skillful except for very-short-lead predictions of very-intense hurricanes due to the lack of storm-scale data assimilation to initialize these forecasts. The model is capable of reasonably predicting rapid intensification and internal dynamics such as eyewall replacement cycles and resulting structural evolution. My presentation will characterize MPAS-Atmosphere’s performance in predicting hurricane track, intensity, and structure, emphasizing highly impactful Hurricanes Francine, Helene, and Milton, and discuss our plans for future MPAS-Atmosphere modeling system development.
Bio
Dr. Clark Evans is a Research Physical Scientist and Physics Branch Chief with the Earth Prediction Advancement Division of NOAA’s Global Systems Laboratory (GSL) in Boulder, CO, a role in which he has served since July 2024. Prior to joining GSL, he was a Professor and Chair of Atmospheric Sciences at the University of Wisconsin-Milwaukee, where he had been employed since 2011. He completed his B.S., M.S., and Ph.D. in Meteorology at Florida State University in 2004, 2006, and 2009, respectively, and was an Advanced Study Program postdoctoral fellow at the National Center for Atmospheric Research from 2009-11. His research interests include improving our understanding and predictability of high-impact weather, particularly tropical cyclones, severe convective storms, and midlatitude cyclones. He has published twenty-six papers in the refereed literature, many of them involving students as lead or coauthors, and his research has been supported by $4.7 million in funded awards. He currently serves as an Editor for the American Meteorological Society’s Monthly Weather Review peer-reviewed journal and as the Incoming Commissioner of the American Meteorological Society’s Scientific and Technological Activities Commission. He lives along the Colorado Front Range with his wife, Susanna, and son, Lucas.
