Abstract
AbstractAn idealized eddy‐resolving ocean basin, closely resembling the North Pacific Ocean, is simulated using MITgcm. We identify rotationally coherent Lagrangian vortices (RCLVs) and sea surface height (SSH) eddies based on the Lagrangian and Eulerian framework, respectively. General statistical results show that RCLVs have a much smaller coherent core than SSH eddies with the ratio of radius is about 0.5. RCLVs are often enclosed by SSH anomaly contours, but SSH eddy identification method fails to detect more than half of RCLVs. Based on their locations, two types of eddies are classified into three categories: overlapping RCLVs and SSH eddies, nonoverlapping SSH eddies, and nonoverlapping RCLVs. Using Lagrangian particles, we examine the processes of leakage and intrusion around SSH eddies. For overlapping SSH eddies, over the lifetime, the material coherent core only accounts for about 25% and about 50% of initial water leak from eddy interior. The remaining 25% of water can still remain inside the boundary, but only in the form of filaments outside the coherent core. For nonoverlapping SSH eddies, more water leakage (about 60%) occurs at a faster rate. Guided by the number and radius of SSH eddies, fixed circles and moving circles are randomly selected to diagnose the material flux around these circles. We find that the leakage and intrusion trends of moving circles are quite similar to that of nonoverlapping SSH eddies, suggesting that the material coherence properties of nonoverlapping SSH eddies are not significantly different from random pieces of ocean with the same size.
Highlights
Mesoscale eddies with horizontal spatial scales broadly between tens and a few hundred kilometers are ubiquitous structures in the ocean (Fu et al (2010)), transporting and redistributing mass, heat, salt, potential vorticity, and other biochemical tracers throughout the ocean
rotationally coherent Lagrangian vortices (RCLVs) are often enclosed by sea surface height (SSH) anomaly contours, but SSH eddy identification method fails to detect more than half of RCLVs
Having described the statistics of Lagrangian vortices and Eulerian eddies, we focus on the core issue of our study: how leaky are the Eulerian eddies in terms of material transport?
Summary
Mesoscale eddies with horizontal spatial scales broadly between tens and a few hundred kilometers are ubiquitous structures in the ocean (Fu et al (2010)), transporting and redistributing mass, heat, salt, potential vorticity, and other biochemical tracers throughout the ocean. This transport is believed to have significant impacts on the large-scale ocean circulation, marine ecosystems, and long-term Earth climate (e.g., Jayne and Marotzke (2001); Dong et al (2014); Zhang et al (2014); Gaube et al (2015); Griffies et al (2015); Kouketsu et al (2016)). We seek to examine the extent to which the eddies detected by different methods maintain coherence over their lifetimes
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