Topographic Steering of the Upper Arctic Ocean Circulation by Deep Flows

Topographic Steering of the Upper Arctic Ocean Circulation by Deep Flows

Dynamically, the Arctic Ocean is characterised by the presence of closed f/H contours, where f is the Coriolis parameter and H the depth. On closed f/H contours, a net integrated surface wind stress can theoretically drive relatively strong near-bottom flows. Nevertheless, the Rossby number of the l...

Full description

Saved in:
Bibliographic Details
Main Authors: Johan Nilsson, Jan-Adrian H. Kallmyr, Pål Erik Isachsen
Format: Article
Language:English
Published: Stockholm University Press 2024-11-01
Series:Tellus: Series A, Dynamic Meteorology and Oceanography
Subjects:
arctic ocean circulation
topographic steering
ekman pumping
mesoscale eddies
Online Access:https://account.a.tellusjournals.se/index.php/su-j-tadmo/article/view/4072
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Dynamically, the Arctic Ocean is characterised by the presence of closed f/H contours, where f is the Coriolis parameter and H the depth. On closed f/H contours, a net integrated surface wind stress can theoretically drive relatively strong near-bottom flows. Nevertheless, the Rossby number of the large-scale time-mean flow in the Arctic Ocean is estimated to be small, implying that the near-bottom flow should essentially be aligned with the f/H contours. Observations indicate that the time-mean surface flow also tends to follow the f/H contours, which in the Arctic are essentially controlled by H. To examine mechanisms that can organise the Arctic Ocean surface flow along the topography, we use a two-layer large-scale geostrophic model on an f-plane (exploiting that f/H variations are dominated by depth variations). The effect of time-dependent baroclinic eddies is represented as an eddy diffusion of the upper-layer thickness. We study how wind forcing, stratification, eddy diffusivity and bottom friction affect the topographic steering of the time-mean surface flow, introducing relevant non-dimensional parameters. The analyses suggest that the Arctic Ocean is in a regime where strong along-isobath near-bottom flows can align the buoyancy field and, thereby, the surface currents with the topography. We then discuss the model results in relation to satellite-derived surface currents in the Arctic Ocean and briefly consider additional mechanisms that can align surface flows with the topography.
ISSN:1600-0870

Similar Items