Deep Learning for Subgrid‐Scale Turbulence Modeling in Large‐Eddy Simulations of the Convective Atmospheric Boundary Layer

Yu Cheng; Marco G. Giometto; Pit Kauffmann; Ling Lin; Chen Cao; Cody Zupnick; Harold Li; Qi Li; Yu Huang; Ryan Abernathey; Pierre Gentine

doi:10.1029/2021MS002847

Journal of Advances in Modeling Earth Systems (May 2022)

Deep Learning for Subgrid‐Scale Turbulence Modeling in Large‐Eddy Simulations of the Convective Atmospheric Boundary Layer

Yu Cheng,
Marco G. Giometto,
Pit Kauffmann,
Ling Lin,
Chen Cao,
Cody Zupnick,
Harold Li,
Qi Li,
Yu Huang,
Ryan Abernathey,
Pierre Gentine

Affiliations

Yu Cheng: Department of Earth and Environmental Engineering Columbia University New York NY USA
Marco G. Giometto: Department of Civil Engineering and Engineering Mechanics Columbia University New York NY USA
Pit Kauffmann: Capstone Project at Data Science Institute Columbia University New York NY USA
Ling Lin: Capstone Project at Data Science Institute Columbia University New York NY USA
Chen Cao: Capstone Project at Data Science Institute Columbia University New York NY USA
Cody Zupnick: Capstone Project at Data Science Institute Columbia University New York NY USA
Harold Li: Department of Earth and Environmental Engineering Columbia University New York NY USA
Qi Li: School of Civil and Environmental Engineering Cornell University Ithaca NY USA
Yu Huang: Department of Earth and Environmental Engineering Columbia University New York NY USA
Ryan Abernathey: Department of Earth and Environmental Sciences Columbia University Palisades NY USA
Pierre Gentine: Department of Earth and Environmental Engineering Columbia University New York NY USA

DOI: https://doi.org/10.1029/2021MS002847
Journal volume & issue: Vol. 14, no. 5
pp. n/a – n/a

Abstract

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Abstract In large‐eddy simulations, subgrid‐scale (SGS) processes are parameterized as a function of filtered grid‐scale variables. First‐order, algebraic SGS models are based on the eddy‐viscosity assumption, which does not always hold for turbulence. Here we apply supervised deep neural networks (DNNs) to learn SGS stresses from a set of neighboring coarse‐grained velocity from direct numerical simulations of the convective boundary layer at friction Reynolds numbers Reτ up to 1243 without invoking the eddy‐viscosity assumption. The DNN model was found to produce higher correlation between SGS stresses compared to the Smagorinsky model and the Smagorinsky‐Bardina mixed model in the surface and mixed layers and can be applied to different grid resolutions and various stability conditions ranging from near neutral to very unstable. The DNN model can capture key statistics of turbulence in a posteriori (online) tests when applied to large‐eddy simulations of the atmospheric boundary layer.

Published in Journal of Advances in Modeling Earth Systems

ISSN: 1942-2466 (Online)
Publisher: American Geophysical Union (AGU)
Country of publisher: United States
LCC subjects: Geography. Anthropology. Recreation: Physical geography; Geography. Anthropology. Recreation: Oceanography
Website: http://agupubs.onlinelibrary.wiley.com/hub/journal/10.1002/(ISSN)1942-2466/

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