About this Event
TITLE: DATA-DRIVEN CONSTRAINT OF CLOUD MICROPHYSICS UNCERTAINTY AT GLOBAL + PROCESS-LEVEL SCALES
Speaker: Marcus van Lier-Walqui
Date: July 25, 2024
Time: 12:00 p.m.
Format: Hybrid
Virtual: Zoom link provided upon registration
In-person: Columbia Innovation Hub, 2276 12th Avenue, Second Floor, Room 202, New York, NY 10027
*Please note that in-person space is limited.*
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Abstract: Cloud microphysical processes---those that make and evolve clouds and precipitation---are critical for understanding both how Earth’s climate will respond to anthropogenic emissions as well as how high-impact weather systems such as thunderstorms evolve. However, these processes are challenging to tackle via data-driven methods, because there is no true reference model---cloud microphysical processes are uncertain at every scale. Data-driven approaches that leverage the formalism of Bayesian statistics and machine learning must therefore aim to improve reduced-order models with both the (flawed, incomplete) structurally complex models that do exist, as well as real observations. In many cases, errors are primarily structural in origin, rather than parametric, and we attempt to systematize the selection of reduced-order model structure. I will discuss efforts to improve cloud microphysics, within both high resolution large-eddy simulations, as well as for global Earth system models such as the NASA GISS ModelE3, the DOE’s E3SM, and CESM. I will present recent breakthroughs in these efforts, and remaining challenges towards data-driven development and constraint at all scales.
Bio: Dr. van Lier-Walqui is an Associate Research Scientist and has worked at CCSR since 2013. His expertise is in using Bayesian inference methods to estimate parameters and quantify uncertainty in physical models of clouds and precipitation. This involves making comparison between observations, such as advanced polarimetric and profiling radars, and model simulations of weather. These efforts leverage the rich microphysical information content of observational systems to improve our understanding and model representation of cloud and precipitation processes. Furthermore, the Bayesian methodologies used allow for robust estimation of uncertainty that can inform forecast representations of physical process uncertainty, e.g. via probabilistic forecast ensembles.
Learn More: LEAP
MARCUS van LIER-WALQUI (Columbia)
Event Venue & Nearby Stays
LEAP, 2276 12th Ave, New York, United States
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