Dynamics paradigm of geostrophic cross-isobath transport (GCT) over highly variable shelf topographies
ID:710 View Protection:ATTENDEE Updated Time:2024-10-13 03:57:12 Hits:739 Oral Presentation

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

Duration:15min

Session:S24 Session 24-Estuaries and Coastal Environments Stress - Observations and Modelling » S24-3Estuaries and Coastal Environments Stress - Observations and Modelling

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Abstract
Flow-topography interaction is the key dynamics that governs the circulation over highly variable continental shelf, and its underlying dynamics remains as an active research topic. Based on results of observations and 3D process-oriented numerical modeling, we illustrated the 3D upwelling circulation and variability over the characteristic steep, concave, uniform (2D) and widened shelf topographic regimes in Northern South China Sea (NSCS). We presented the geostrophic cross-isobath transport (GCT) dynamics associated with the formation of the along-isobath pressure gradient force (PGFy*) to interpret the unique circulation and variability of wind-driven upwelling circulation over these shelf topographic regimes. We found that an intensified upslope cross-isobath transport (u*) occurs locally over the steep, concave, and widened shelf regimes, as a result of GCT. Built on vorticity dynamics, we derived the GCT dynamics and analytically and numerically found that PGFy*  over variable topographic regimes is induced by bottom stress curl arising from shear vorticity or curvature vorticity of the upwelling jet (v*) in a non-stratified flow with low Rossby number. Whereas nonlinearity and stratification predominate the GCT via nonlinear vorticity advection and the Joint Effect of Baroclinity and Relief (JEBAR). Meandering v* guided by variable shelf topography interacts with u* and jointly controls the variable upwelling circulation through flow-topography interaction. This study conducts holistic analyses based on the framework of GCT dynamics to enrich the wind-driven shelf circulation dynamics over different shelf topographic regimes.
 
Keywords
Geostrophic cross-isobath transport; along-isobath pressure gradient force; flow-topography interaction; topographically intensified upwelling
Speaker
Chi Wing (Rex) Hui
Research Assistant Hong Kong University of Science and Technology

Submission Author
Jianping Gan The Hong Kong University of Science and Technology; Professor;Jianping Gan
Chi Wing (Rex) Hui Hong Kong University of Science and Technology
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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
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