The Separation of the East Australian Current: A Lagrangian Approach to Potential Vorticity and Upstream Control

Stefanie Leonore Ypma, Delft University of Technology, Delft, Netherlands, Erik VanSebille, Imperial College London, Grantham Institue, London, United Kingdom, Andrew E Kiss, Australian National University, Research School of Earth Sciences, Canberra, Australia and Paul Spence, University of New South Wales, Climate Change Research Centre, Sydney, Australia
Abstract:
The East Australian Current (EAC) is the western boundary current flowing along the east coast of Australia separating from the coast at approximately 34°S. After the separation two main pathways can be distinguished, the eastward flowing Tasman Front and the extension of the EAC flowing southwards. The area south of the separation latitude is eddy-rich, making the EAC region a variable system. Little is known of the properties of the water masses that separate at the bifurcation of the EAC. I will present new insights from the Lagrangian perspective, where the water masses that veer east and those that continue south are tracked in an eddy-permitting numerical model. The transport along the two pathways is computed, and a 1:3 ratio between transport in the EAC extension and transport in the Tasman Front is found. The results show that the `fate' of the particles is to first order already determined by the particle distribution within the EAC current upstream of the separation latitude, where 83% of the particles following the EAC extension originate from below 640m and 72% of the particles following the Tasman Front originate from the top 640m depth at 28°S. The separation and pathways are controlled by the structure of the isopycnals in this region. Analysis of anomalies in potential vorticity show that in the region where the two water masses overlap, the fate of the water depends on the presence of anticyclonic eddies that push isopycnals down and therefore enable particles to travel further south.