Local and Remote Influences on the Heat Content of the Labrador Sea: an Adjoint Sensitivity Study

The Labrador Sea is one of the few regions on the planet where the interior ocean can exchange heat directly with the atmosphere via strong, localized, wintertime convection, with possible implications for the state of North Atlantic climate and global surface warming. Using an observationally-const...

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Bibliographic Details
Main Authors: Jones, Dan, Forget, Gael, Sinha, Bablu, Josey, Simon, Boland, Emma, Meijers, Andrew, Shuckburgh, Emily
Format: Report
Language:unknown
Published: EarthArXiv 2018
Subjects:
Physical Sciences and Mathematics
Oceanography and Atmospheric Sciences and Meteorology
Oceanography
FOS Earth and related environmental sciences
Greenland
Irminger Sea
Iceland
Labrador Sea
north atlantic current
North Atlantic
Online Access:https://dx.doi.org/10.17605/osf.io/kc2u9
https://eartharxiv.org/kc2u9/
Description
Summary:The Labrador Sea is one of the few regions on the planet where the interior ocean can exchange heat directly with the atmosphere via strong, localized, wintertime convection, with possible implications for the state of North Atlantic climate and global surface warming. Using an observationally-constrained ocean adjoint model, we find that annual mean Labrador Sea heat content is sensitive to temperature/salinity changes (1) along potential source water pathways (e.g. the subpolar gyre, the North Atlantic Current, the Gulf Stream) and (2) along the West African and European shelves, which are not significant source water regions for the Labrador Sea. The West African coastal/shelf adjustment mechanism, which may be excited by changes in along-shelf wind stress, involves pressure anomalies that propagate along a coastal waveguide towards Greenland, changing the across-shelf pressure gradient in the North Atlantic and altering heat convergence in the Labrador Sea. We also find that non-local (in space and time) heat fluxes (e.g. in the Irminger Sea, the seas south of Iceland) can have a strong impact on Labrador Sea heat content. Understanding and predicting the state of the Labrador Sea and its potential impacts on North Atlantic climate and global surface warming will require monitoring of oceanic and atmospheric properties at remote sites in the Irminger Sea, the subpolar gyre, and along the West African and European shelf/coast system, among others.

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