3D Flow Structures During Upwelling Events in Lakes of Moderate Size

Upwelling can impact water quality dynamics in stratified water bodies. Conceptual models generally classify the upwelling response to winds in lakes into either a non-rotational (2D, closed-basin) model or a rotational (coastal upwelling) counterpart. The non-rotational model is broadly applied in rotationally influenced lakes. The upwelling response to winds in stratified lakes may exhibit elements of both conceptual models. Here, we present the results of simulations with an accurate three-dimensional numerical model of a lake of moderate size (Lake Tahoe, California-Nevada, USA), and focus our analyses on addressing the influence of the Coriolis force during the upwelling setup and relaxation phases. Upwelling was observed at the upwind boundary as well as along the coast to the left of the mean wind direction due to Ekman-driven divergence. On the downwind shoreline, where downwelling occurs, alongshore currents appeared in response to wind forcing. Following the relaxation of the wind, our simulations reveal, for the first time, the existence of powerful cyclonic alongshore currents in lakes of moderate size, which are found to be in quasi-geostrophic balance. These currents followed the characteristics of coastal jets often observed in large lakes and the coastal ocean. Our work leads us to conclude that upwelling setup in lakes with length scales approximate to 20 km and Burger numbers S < 1, exhibits a combination of dynamics predicted by both the non-rotational, 2D, closed basin model, and the rotational coastal-upwelling conceptual model.

Automated summary

Upwelling can affect water quality dynamics in stratified water bodies. Numerical simulations reveal a combination of rotational and non-rotational characteristics of upwelling response in lakes, with the influence of the Coriolis force.