Impact of internal wave drag on Arctic sea ice

A parameterization of the impact of internal waves on momentum transfer at the sea-ice–ocean interface based on previous work by McPhee has been implemented in a sea-ice model for the first time. The ice–ocean drag from internal waves is relevant for shallow mixed layer depth and the presence of a density jump at the pycnocline and is also a function of the strength of the stratification beneath the ocean mixed layer and geometry of the ice interface. We present results from a coupled sea-ice–ocean model where the parameterization of internal wave drag has been implemented. We conducted simulations spanning the years from 2000 to 2017. We find a deceleration of ice drift by 5–8% in both winter and summer, but with significant spatial and temporal variation reaching seasonal average values of ∼10%. The spatial variation of ice transport leads to local impacts on deformed ice of magnitude ∼0.05 m (2–5%), and reductions in ocean-to-ice heat fluxes of ∼1Wm−2, and a decrease in bottom melt of ∼0.02–0.04 cm d−1. There is an increase of up to 15% in thickness and ice concentration in the Canadian Arctic and a 10% overall impact on the total sea-ice volume.

Details

Publication status:
Published
Author(s):
Authors: Flocco, Daniela, Feltham, Daniel, Schroeder, David, Aksenov, Yevgeny ORCIDORCID record for Yevgeny Aksenov, Siahaan, Antony, Tsamados, Michel

On this site: Antony Siahaan
Date:
30 October, 2024
Journal/Source:
Annals of Glaciology
Page(s):
1-16
Link to published article:
https://doi.org/10.1017/aog.2024.37