Data-Driven Probabilistic Air-Sea Flux Parameterization

Jiarong Wu; Pavel Perezhogin; David John Gagne; Brandon Reichl; Aneesh C. Subramanian; Elizabeth Thompson; Laure Zanna

Data-Driven Probabilistic Air-Sea Flux Parameterization

Jiarong Wu, Pavel Perezhogin, David John Gagne, Brandon Reichl, Aneesh C. Subramanian, Elizabeth Thompson, Laure Zanna

Machine Integration and Learning for Earth Systems

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Abstract

Accurately quantifying air-sea fluxes is important for understanding air-sea interactions and improving coupled weather and climate systems. This study introduces a probabilistic framework to represent the highly variable nature of air-sea fluxes, which is missing in deterministic bulk algorithms. Assuming Gaussian distributions conditioned on the input variables, we use artificial neural networks and eddy-covariance measurement data to estimate the mean and variance by minimizing negative log-likelihood loss. The trained neural networks provide alternative mean flux estimates to existing bulk algorithms, and quantify the uncertainty around the mean estimates. Stochastic parameterization of air-sea turbulent fluxes can be constructed by sampling from the predicted distributions. Tests in a single-column forced upper-ocean model suggest that changes in flux algorithms influence sea surface temperature and mixed layer depth seasonally. The ensemble spread in stochastic runs is most pronounced during spring restratification.

Original language	English
Journal	arXiv
State	E-pub ahead of print - Mar 1 2025

Keywords

Physics - Atmospheric and Oceanic Physics
Computer Science - Machine Learning
Statistics - Applications
Statistics - Machine Learning

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http://adsabs.harvard.edu/abs/2025arXiv250303990W

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title = "Data-Driven Probabilistic Air-Sea Flux Parameterization",

abstract = "Accurately quantifying air-sea fluxes is important for understanding air-sea interactions and improving coupled weather and climate systems. This study introduces a probabilistic framework to represent the highly variable nature of air-sea fluxes, which is missing in deterministic bulk algorithms. Assuming Gaussian distributions conditioned on the input variables, we use artificial neural networks and eddy-covariance measurement data to estimate the mean and variance by minimizing negative log-likelihood loss. The trained neural networks provide alternative mean flux estimates to existing bulk algorithms, and quantify the uncertainty around the mean estimates. Stochastic parameterization of air-sea turbulent fluxes can be constructed by sampling from the predicted distributions. Tests in a single-column forced upper-ocean model suggest that changes in flux algorithms influence sea surface temperature and mixed layer depth seasonally. The ensemble spread in stochastic runs is most pronounced during spring restratification.",

keywords = "Physics - Atmospheric and Oceanic Physics, Computer Science - Machine Learning, Statistics - Applications, Statistics - Machine Learning",

author = "Jiarong Wu and Pavel Perezhogin and Gagne, \{David John\} and Brandon Reichl and Subramanian, \{Aneesh C.\} and Elizabeth Thompson and Laure Zanna",

year = "2025",

month = mar,

day = "1",

language = "English",

journal = "arXiv",

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TY - JOUR

T1 - Data-Driven Probabilistic Air-Sea Flux Parameterization

AU - Wu, Jiarong

AU - Perezhogin, Pavel

AU - Gagne, David John

AU - Reichl, Brandon

AU - Subramanian, Aneesh C.

AU - Thompson, Elizabeth

AU - Zanna, Laure

PY - 2025/3/1

Y1 - 2025/3/1

N2 - Accurately quantifying air-sea fluxes is important for understanding air-sea interactions and improving coupled weather and climate systems. This study introduces a probabilistic framework to represent the highly variable nature of air-sea fluxes, which is missing in deterministic bulk algorithms. Assuming Gaussian distributions conditioned on the input variables, we use artificial neural networks and eddy-covariance measurement data to estimate the mean and variance by minimizing negative log-likelihood loss. The trained neural networks provide alternative mean flux estimates to existing bulk algorithms, and quantify the uncertainty around the mean estimates. Stochastic parameterization of air-sea turbulent fluxes can be constructed by sampling from the predicted distributions. Tests in a single-column forced upper-ocean model suggest that changes in flux algorithms influence sea surface temperature and mixed layer depth seasonally. The ensemble spread in stochastic runs is most pronounced during spring restratification.

AB - Accurately quantifying air-sea fluxes is important for understanding air-sea interactions and improving coupled weather and climate systems. This study introduces a probabilistic framework to represent the highly variable nature of air-sea fluxes, which is missing in deterministic bulk algorithms. Assuming Gaussian distributions conditioned on the input variables, we use artificial neural networks and eddy-covariance measurement data to estimate the mean and variance by minimizing negative log-likelihood loss. The trained neural networks provide alternative mean flux estimates to existing bulk algorithms, and quantify the uncertainty around the mean estimates. Stochastic parameterization of air-sea turbulent fluxes can be constructed by sampling from the predicted distributions. Tests in a single-column forced upper-ocean model suggest that changes in flux algorithms influence sea surface temperature and mixed layer depth seasonally. The ensemble spread in stochastic runs is most pronounced during spring restratification.

KW - Physics - Atmospheric and Oceanic Physics

KW - Computer Science - Machine Learning

KW - Statistics - Applications

KW - Statistics - Machine Learning

M3 - Article

JO - arXiv

JF - arXiv

ER -

Data-Driven Probabilistic Air-Sea Flux Parameterization

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Keywords

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