A new tool was developed for large volume sampling to facilitate marine microbiology and biogeochemical studies. It was developed for remotely operated vehicle and hydrocast deployments, and allows for rapid collection of multiple sample types from the water column and dynamic, variable environments such as rising hydrothermal plumes. It was used successfully during a cruise to the hydrothermal vent systems of the Mid-Cayman Rise. The Suspended Particulate Rosette V2 large volume multi-sampling system allows for the collection of 14 sample sets per deployment. Each sample set can include filtered material, whole (unfiltered) water, and filtrate. Suspended particulate can be collected on filters up to 142 mm in diameter and pore sizes down to 0.2 μm. Filtration is typically at flowrates of 2 L min-1. For particulate material, filtered volume is constrained only by sampling time and filter capacity, with all sample volumes recorded by digital flowmeter. The suspended particulate filter holders can be filled with preservative and sealed immediately after sample collection. Up to 2 L of whole water, filtrate, or a combination of the two, can be collected as part of each sample set. The system is constructed of plastics with titanium fasteners and nickel alloy spring loaded seals. There are no ferrous alloys in the sampling system. Individual sample lines are prefilled with filtered, deionized water prior to deployment and remain sealed unless a sample is actively being collected. This system is intended to facilitate studies concerning the relationship between marine microbiology and ocean biogeochemistry.
For benthic fauna endemic to hydrothermal vents, larval dispersal in the plankton is required for maintenance of populations and colonization of new vents. Dispersal distances in the plankton are expected to be influenced by vertical positioning into horizontal currents, and larval survival in the plankton as well as encounter rates for settlement cues may be influenced by swimming speed. Here, we present the first quantitative measurements of swimming speeds of polychaete larvae collected near deep-sea hydrothermal vents. We focused on three polychaete larvae of different morphotypes, with two morphotypes identified genetically to Capitellidae and Spionidae. Mean swimming speeds and helical parameters of the deep-sea polychaete larvae (measured at 1 atm) were similar to values reported for shallow-water polychaete larvae, with mean helical 3D swimming speeds ranging from 0.8-1.4 mmÁs À1 . To account for swimming that deviated from helical patterns, we developed a new method to reconstruct 3D swimming trajectories, using the 2D track and larval orientation. Speeds were generally faster for downward swimming, with mean vertical displacement speeds ranging from 0.6-0.8 mmÁs À1 downward as compared with 0.2-0.6 mmÁs À1 upward. Mean swimming speeds and helical parameters differed among the individuals. Our results are a first step towards constraining a behavioral component in models of larval dispersal between deep-sea hydrothermal vents.
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