The Influence of Synoptic Wind on Coastal Circulation Dynamics

TL;DR

This study investigates how synoptic wind influences land-sea breeze circulations through simulations and scaling analysis, revealing asymmetric regimes and classifying circulation types based on external and internal parameters.

Contribution

It introduces a comprehensive model linking synoptic forcing and thermal effects to land-sea breeze regimes, with a novel classification method using velocity and heat flux profiles.

Findings

Deep land-sea breezes occur with minimal synoptic influence.

Circulation height decreases with increasing synoptic winds across-shore.

A new classification scheme for land-sea breeze regimes is proposed.

Abstract

Particularly challenging classes of heterogeneous surfaces are ones where strong secondary circulations are generated, potentially dominating the flow dynamics. In this study, we focus on land-sea breeze circulations (LSBs) resulting from surface thermal contrasts in the presence of increasing synoptic pressure forcing. The relative importance and orientation of the thermal and synoptic forcings are measured through two dimensionless parameters: a bulk Richardson number (Mg is the geostrophic wind magnitude and Wstar a convective buoyant velocity scale), and the angle alpha between the shore and geostrophic wind. Large eddy simulations reveal the emergence of various regimes where the dynamics are shown to be asymmetric with respect to alpha. Along-shore cases result in deep LSBs similar to the quiescent scenario (zero synoptic background), irrespective of the strength of Mg. Across-shore simulations exhibit a circulation cell that decreases in height with increasing synoptic forcing. However, at the highest synoptic winds simulated, the circulation cell is advected away with sea-to-land winds, while a shallow circulation persists for land-to-sea cases. Scaling analysis that relates the internal parameters Qshore (net shore volumetric flux) and qshore (net shore advected heat flux) to the external input parameters Mg and Wstar results in a succinct model of the shore fluxes that also helps explain the physical implications of the identified LSBs. Finally, the vertical profiles of the shore-normal velocity and shore-advected heat flux are used, with the aid of k-means clustering, to independently classify the LSBs in the (Ri, alpha) regime space diagram (canonical LSB, sea-driven LSB, land-driven LSB, and advected LSB), corroborating our visual categorization.