Abstract
The water masses exiting the Labrador Sea, and in particular the dense water mass formed by convection (i.e. Labrador Sea Water, LSW), are important components of the Atlantic Meridional Overturning Circulation (AMOC). Several studies have questioned the connection of the LSW production to the AMOC variability. This is partly due to the limited understanding of how this locally formed water mass leaves the interior of the Labrador Sea. In this study, the pathways and the timescales of the water masses exiting the Labrador Sea via the boundary current are investigated by Lagrangian particle tracking. This method is applied to the output of a strongly-eddying idealized model that is capable of representing the essential physical processes involved in the cycle of convection and restratification in the Labrador Sea. The Lagrangian trajectories reveal that prior to exiting the domain the water masses follow either a fast route within the boundary current or a slower route that involves boundary current-interior exchanges. The densest water masses exiting the Labrador Sea stem from this slow route, where particles experience strong water mass transformation while in the interior. In contrast, the particles that follow the fast route experience water mass transformation in the boundary current at the western side of the domain only, yielding a lighter product. Although both routes carry roughly the same transport, we show that 60% of the overturning in density space is associated with the volume transport carried by particles that follow the slow route. This study further highlights that the export of dense water masses, which is governed by the eddy activity in the basin, yields export timescales that are usually longer than a year. This underlines the necessity of resolving the mesoscale features required to capture the interior–boundary current exchange in order to correctly represent the export of the LSW.
Highlights
The Atlantic Meridional Overturning Circulation (AMOC) describes the conversion of lighter, shallow Atlantic water masses flowing northward into denser, deep water masses flowing southward, involving diabatic processes like deep convection in the marginal seas of the North Atlantic
The water masses exiting the Labrador Sea, and in particular the dense water mass formed by convection (i.e. Labrador Sea Water, LSW), are important components of the Atlantic Meridional Overturning Circulation (AMOC)
The upstream pathways of the water masses exiting the Labrador Sea have been investigated from a Lagrangian perspective, with a focus on the exchange between the boundary current and the interior and the water mass transformation that occurs within the domain
Summary
The Atlantic Meridional Overturning Circulation (AMOC) describes the conversion of lighter, shallow Atlantic water masses flowing northward into denser, deep water masses flowing southward, involving diabatic processes like deep convection in the marginal seas of the North Atlantic. The recent highly idealized numerical study of a convective marginal sea by Brüggemann and Katsman (2019) clearly highlights the important role of the exchange of waters between the interior and the boundary current, which in turn is governed by the eddy activity, for the export pathways of convected water and the associated timescales. Their results indicated that the densest water masses are formed in the interior and are laterally steered towards the region of high eddy activity and entrained in the boundary current, following an indirect route to leave the marginal sea.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
