Jessica C. Garwood scite author profile

Coastal physical processes are essential for the cross-shore transport of meroplanktonic larvae to their benthic adult habitats. To investigate these processes, we released a swarm of novel, trackable, subsurface vehicles, the Mini-Autonomous Underwater Explorers (M-AUEs), which we programmed to mimic larval depth-keeping behavior. The M-AUE swarm measured a sudden net onshore transport of 30-70 m over 15-20 min, which we investigated in detail. Here, we describe a novel transport mechanism of depth-keeping plankton revealed by these observations. In situ measurements and models showed that, as a weakly nonlinear internal wave propagated through the swarm, it deformed surface-intensified, along-isopycnal background velocities downward, accelerating depth-keeping organisms onshore. These higher velocities increased both the depth-keepers' residence time in the wave and total cross-shore displacement, leading to wave-induced transports twice those of fully Lagrangian organisms and four times those associated with the unperturbed background currents. Our analyses also show that integrating velocity time series from virtual larvae or mimics moving with the flow yields both larger and more accurate transport estimates than integrating velocity time series obtained at a point (Eulerian). The increased cross-shore transport of organisms capable of vertical swimming in this wave/background-current system is mathematically analogous to the increase in onshore transport associated with horizontal swimming in highly nonlinear internal waves. However, the mechanism described here requires much weaker swimming speeds (mm s −1 vs. cm s −1 ) to achieve significant onshore transports, and meroplanktonic larvae only need to orient themselves vertically, not horizontally.

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Stokes drift of plankton in linear internal waves: Cross‐shore transport of neutrally buoyant and depth‐keeping organisms

Franks

Garwood

Ouimet

et al. 2019

Limnology & Oceanography

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The meroplanktonic larvae of many invertebrate and vertebrate species rely on physical transport to move them across the shelf to their adult habitats. One potential mechanism for cross‐shore larval transport is Stokes drift in internal waves. Here, we develop theory to quantify the Stokes velocities of neutrally buoyant and depth‐keeping organisms in linear internal waves in shallow water. We apply the analyses to theoretical and measured internal wave fields, and compare results with a numerical model. Near the surface and bottom boundaries, both neutrally buoyant and depth‐keeping organisms were transported in the direction of the wave's phase propagation. However, neutrally buoyant organisms were transported in the opposite direction of the wave's phase at mid depths, while depth‐keeping organisms had zero net transport there. Weakly depth‐keeping organisms had Stokes drifts between the perfectly depth‐keeping and neutrally buoyant organisms. For reasonable wave amplitudes and phase speeds, organisms would experience horizontal Stokes speeds of several centimeters per second—or a few kilometers per day in a constant wave field. With onshore‐polarized internal waves, Stokes drift in internal waves presents a predictable mechanism for onshore transport of meroplanktonic larvae and other organisms near the surface, and offshore transport at mid depths.

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Grain sizes retained by diatom biofilms during erosion on tidal flats linked to bed sediment texture

Garwood

Hill

MacIntyre

et al. 2015

Continental Shelf Research

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Exchange of Plankton, Pollutants, and Particles Across the Nearshore Region

Moulton

Suanda

Garwood

et al. 2023

Annu. Rev. Mar. Sci.

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Exchange of material across the nearshore region, extending from the shoreline to a few kilometers offshore, determines the concentrations of pathogens and nutrients near the coast and the transport of larvae, whose cross-shore positions influence dispersal and recruitment. Here, we describe a framework for estimating the relative importance of cross-shore exchange mechanisms, including winds, Stokes drift, rip currents, internal waves, and diurnal heating and cooling. For each mechanism, we define an exchange velocity as a function of environmental conditions. The exchange velocity applies for organisms that keep a particular depth due to swimming or buoyancy. A related exchange diffusivity quantifies horizontal spreading of particles without enough vertical swimming speed or buoyancy to counteract turbulent velocities. This framework provides a way to determine which processes are important for cross-shore exchange for a particular study site, time period, and particle behavior. Expected final online publication date for the Annual Review of Marine Science, Volume 15 is January 2023. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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Life in Internal Waves

Garwood¹,

Musgrave²,

Lucas³

2020

Oceanog

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