Development of a Handheld Submersible Chemiluminescent Sensor: Quantification of Superoxide at Coral Surfaces.

Reactive oxygen species (ROS) are produced via various photochemical, abiotic, and biological pathways. The low concentration and short lifetime of the ROS superoxide (O2•-) make it challenging to measure in natural systems. Here, we designed, developed, and validated a DIver-operated Submersible Chemiluminescent sensOr (DISCO), the first handheld submersible chemiluminescent sensor. The fluidic system inside DISCO is controlled by two high-precision pumps that introduce sample water and analytical reagents into a mixing cell. The resultant chemiluminescent signal is quantified by a photomultiplier tube, recorded by a miniature onboard computer and monitored in real time via a handheld underwater LED interface. Components are contained within a pressure-bearing housing (max depth 30 m), and an external battery pack supplies power. Laboratory calibrations with filtered seawater verified instrument stability and precision. Field deployment in Cuban coral reefs quantified background seawater-normalized extracellular superoxide concentrations near coral surfaces (0-173 nM) that varied distinctly with coral species. Observations were consistent with previous similar measurements from aquaria and shallow reefs using a standard benchtop system. In situ quantification of superoxide associated with corals was enabled by DISCO, demonstrating the potential application to other shallow water ecosystems and chemical species.

Rapid Mapping of Dissolved Methane and Carbon Dioxide in Coastal Ecosystems Using the ChemYak Autonomous Surface Vehicle.

Coastal ecosystems host high levels of primary productivity leading to exceptionally dynamic elemental cycling in both water and sediments. In such environments, carbon is rapidly cycled leading to high rates of burial as organic matter and/or high rates of loss to the atmosphere and laterally to the coastal ocean in simpler forms, such as carbon dioxide (CO2) and methane (CH4). To better understand carbon cycling across these heterogeneous environments, new technologies beyond discrete sample collection and analysis are needed to characterize spatial and temporal variability. Here, we describe the ChemYak, an autonomous surface vehicle outfitted with a suite of in situ sensors, developed to achieve large spatial scale chemical mapping of these environments. Dissolved methane and carbon dioxide are measured by a laser spectrometer coupled to a gas extraction unit for continuous quantification during operation. The gas-powered vehicle is capable of rapidly surveying the coastal system with an endurance of up to 10 h at operating speeds in excess of 10 km h-1. Here, we demonstrate its ability to spatially characterize distributions of CO2, CH4, oxygen, and nitrate throughout a New England saltmarsh estuary.