Swish floats: an inexpensive neutrally buoyant float to monitor dispersion in coastal seas

Abstract

Neutrally buoyant floats have been widely used to measure flows in the ocean, but deploying them in large numbers can be costly and impractical. This is particularly true near coastlines due to the elevated risk of instrument grounding or vessel collisions, resulting in a lack of subsurface Lagrangian measurements in coastal regions. Here, we describe an inexpensive neutrally buoyant satellite-tracked float (named “Swallow-ish”, or “Swish” floats) which has been designed and tested as a cost-effective strategy to measure subsurface dispersion in coastal areas on timescales up to a month. These autonomous instruments are inexpensive, constructed at a material cost of $300 CAD per unit; lightweight, with a mass of 5.4 kg; isopycnal; and constructed from commercially available components, using recently-available global navigation satellite system technology to provide the user with a point-to-point measure of subsurface transport. We describe the float design, ballasting techniques, and the governing equations that determine their behavior. Further, through 29 deployments in two coastal seas, we calculate an uncertainty budget and determine a ballasting error of ±1.6 g, corresponding to a local depth targeting error of 16–30 m, analyze the float resurfacing data to calculate subsurface dispersion coefficients, and examine the float depth records to quantify the local internal wave field. Finally, we evaluate surface dispersion using the post-resurfacing trajectories. Our findings indicate that Swish floats offer a cost-effective alternative for Lagrangian measurements of subsurface flows in coastal regions.