Shelf-slope exchanges and particle dispersion in Blanes submarine canyon (NW Mediterranean Sea): A numerical study

摘要

A climatological simulation performed with a fine-resolution (similar to 1.2 km) 3D circulation model nested in one-way to a coarse-resolution (similar to 4 km) 3D regional model is used to examine the cross-shelf break water exchange in the Blanes submarine canyon (similar to 41 degrees 00'-41 degrees 46'N; similar to 02 degrees 24'-03 degrees 24'E). A Lagrangian particle-tracking model coupled to the fine-resolution 3D circulation model is used to investigate the role of the incident regional flow (i.e. the Northern Current, NC) and its seasonal variability on the dispersion and residence time of passive particles inside Blanes Canyon. The NC flows southwestward, along the slope, with the coastline to the right. Water is advected offshore/onshore at the upstream/downstream canyon walls, with a net water transport toward the slope (i.e. offshore). The amount of water moved across the shelf break of the upstream wall is approximately three times larger than the amount moved across the shelf break of the downstream wall. This preferential zone for cross-shelf break water exchange is explained by the asymmetric geometry of the canyon and the orientation of the incident current with respect to the canyon bathymetry. Passive particles released upstream Blanes Canyon between the mid-shelf and the upper-slope drift within the NC and accumulate over the shelf edge of the canyon. About half of the particles released at depths above the shelf break move towards shallower areas inside the canyon. In contrast, about two-thirds of particles released below the shelf break move to deeper areas. Particle dispersion is higher under weakly (e.g. winter) than strongly (e.g. summer) stratified conditions. The residence time of passive particles inside the canyon (similar to 4-6 days) is double than the residence time downstream of the canyon, indicating that the canyon acts as an efficient retention zone for passive particles. (C) 2015 Elsevier Ltd. All rights reserved.