Drifter Deployment Strategies to Determine Lagrangian Surface Convergence in Submesoscale Flows

• Published in: Journal of atmospheric and oceanic technology Vol. 41; no. 1; pp. 95 - 112
• Main Authors: Aravind, H. M., Huntley, Helga S., Kirwan, A. D., Allshouse, Michael R.
• Format: Journal Article
• Language: English
• Published: Boston American Meteorological Society 01.01.2024
• Subjects: Accuracy; Algorithms; Biological activity; Convergence; Deployment; Divergence; Drifters; Error analysis; Estimates; Field tests; General circulation models; Global positioning systems; GPS; Kinematics; Local flow; Ocean surface; Oceanographers; Oceans; Pollution control; Pollution dispersion; Polygons; Position measurement; Rescue operations; Uncertainty; Velocity; Vertical advection
• ISSN: 0739-0572; 1520-0426
• DOI: 10.1175/JTECH-D-22-0129.1

Surface convergence in the ocean is associated with accumulation of buoyant pollutants as well as with vertical transport that is important to biological activity. Such surface convergence regions are marked by a high dilation rate, i.e., the finite time Lagrangian average divergence. Dilation-rate observations are most easily derived from the change of the area encompassed by a drifter swarm over time. The technological advances that have enabled the deployment of large numbers of drifters in a single experiment have raised new questions about optimal deployment strategies for extracting dilation-rate information with acceptable accuracy and as much spatial coverage as possible. Using a submesoscale-resolving operational model of the Mediterranean Sea, we analyze synthetic trajectories of drifter polygons to evaluate the impact of the number of drifters and their initial separation on the accuracy of the resulting dilation-rate estimates. The results confirm that estimates improve as the circumradius of the polygon decreases and as more drifters are added, but with only a marginal improvement for drifter polygons containing more than four drifters. Moreover, GPS positions obtained from drifters in the ocean are subject to uncertainty on the order of 2–50 m, and when this uncertainty is taken into account, an optimal circumradius can be identified that balances uncertainty from position measurements with that from the area approximations.