Anisotropic GM and Redi Mixing Parameters in the Global Ocean
ID:1325 View Protection:ATTENDEE Updated Time:2024-10-14 15:28:18 Hits:825 Poster Presentation

Start Time:2025-01-16 20:20(Asia/Shanghai)

Duration:15min

Session:S46 Session 46-Oceanic Mesoscale and Submesoscale Processes: Characteristics, Dynamics & Parameterizations » S46-POceanic Mesoscale and Submesoscale Processes: Characteristics, Dynamics & Parameterizations

No files

Abstract
    Mesoscale eddies are widespread in the ocean, and the mixing processes they induce play a crucial role in the transport of heat and substances, as well as in climate regulation. Consequently, the representation of eddy-induced mixing processes in non-eddy-resolving models significantly impacts the simulation of large-scale ocean circulation and climate change. Previous studies have shown that eddy-induced mixing coefficients vary greatly in space and often differ in different directions (such as meridional and zonal), a phenomenon known as the anisotropy of eddy-induced mixing coefficients. However, due to the lack of direct observational data on eddy-induced mixing in the ocean interior, the global spatial distribution of anisotropic eddy-induced mixing coefficients remains poorly understood. This study integrates the anisotropic isopycnal thickness diffusion scheme (GM scheme) and the along isopycnal diffusion scheme (Redi scheme) using the GECCO (German contribution to the Estimation of the Circulation and Climate of the Ocean) four-dimensional variational assimilation system. By assimilating data from the past 10 years of sea surface and ocean interior observations, we derived the spatial distribution of anisotropic eddy-induced mixing coefficients in the global ocean. The results indicate that both GM and Redi mixing coefficients exhibit significant spatial variability. Specifically, the GM mixing coefficient shows stronger anisotropy, while the Redi mixing coefficient shows weaker anisotropy. Further experiments demonstrate that incorporating anisotropic mixing coefficients can improve the accuracy of model simulations. This finding suggests that including anisotropic eddy-induced mixing coefficients in ocean models can enhance the simulation of large-scale ocean circulation and thermohaline structure, thereby improving our ability to predict and understand the global climate system.

 
Keywords
eddy-induced mixing,parameterization,assimilation
Speaker
Weisheng Yang
PhD Chinese Academy of Sciences;Institute of Oceanology

Submission Author
Weisheng Yang Chinese Academy of Sciences;Institute of Oceanology
Chuanyu Liu Chinese Academy of Sciences;Institute of Oceanology
Submit Comment
Verify Code Change Another
All Comments
Important Date
  • Conference Date

    Jan 13

    2025

    to

    Jan 17

    2025

  • Sep 27 2024

    Draft paper submission deadline

  • Feb 17 2025

    Registration deadline

Sponsored By
State Key Laboratory of Marine Environmental Science, Xiamen University
Organized By
State Key Laboratory of Marine Environmental Science, Xiamen University
Department of Earth Sciences, National Natural Science Foundation of China
Contact Information