This project is conducting seasonal deployments to investigate carbonate chemistry and monitor ocean acidification in the Mid-Atlantic Bight. The glider used for the automated observation includes an integrated deep rated version of the Ion Sensitive Field Effect Transistor (ISFET)-based pH sensor. The pH sensor unit is complemented with existing glider sensors including a CTD, a WETLabs FLBBCD ECO puck configured for simultaneous chlorophyll fluorescence and optical backscatter measurements, and an Aanderaa Optode for measuring dissolved oxygen.

This project is conducting seasonal deployments to investigate carbonate chemistry and monitor ocean acidification in the Mid-Atlantic Bight. The glider used for the automated observation includes an integrated deep rated version of the Ion Sensitive Field Effect Transistor (ISFET)-based pH sensor. The pH sensor unit is complemented with existing glider sensors including a CTD, a WETLabs FLBBCD ECO puck configured for simultaneous chlorophyll fluorescence and optical backscatter measurements, and an Aanderaa Optode for measuring dissolved oxygen.

This project is conducting seasonal deployments to investigate carbonate chemistry and monitor ocean acidification in the Mid-Atlantic Bight. The glider used for the automated observation includes an integrated deep rated version of the Ion Sensitive Field Effect Transistor (ISFET)-based pH sensor.

This project is conducting seasonal deployments to investigate carbonate chemistry and monitor ocean acidification in the Mid-Atlantic Bight. The glider used for the automated observation includes an integrated deep rated version of the Ion Sensitive Field Effect Transistor (ISFET)-based pH sensor. The pH sensor unit is complemented with existing glider sensors including a CTD, a WETLabs FLBBCD ECO puck configured for simultaneous chlorophyll fluorescence and optical backscatter measurements, and an Aanderaa Optode for measuring dissolved oxygen.

The Predictions of AcousticS with Smart Experimental Networks of GlidERS (PASSENGERS) project is a partnership between universities and the Naval Research Laboratory to improve the capability of data-assimilative ocean models to predict acoustic propagation in dynamic oceanography environments. It includes the deployment of teams of gliders in small (10 km) spatial footprints with integrated passive acoustics focused on mapping the physical and acoustic environment in the dynamic region of the Atlantis II Seamounts.

The Predictions of AcousticS with Smart Experimental Networks of GlidERS (PASSENGERS) project is a partnership between universities and the Naval Research Laboratory to improve the capability of data-assimilative ocean models to predict acoustic propagation in dynamic oceanography environments. It includes the deployment of teams of gliders in small (10 km) spatial footprints with integrated passive acoustics focused on mapping the physical and acoustic environment in the dynamic region of the Atlantis II Seamounts.

Glider deployed as part of the CONsortium for oil spill exposure pathways in COastal River-Dominated Ecosystems (CONCORDE). The goal of the project is to use a combination of observations and numerical modeling to Characterize the complex 4D physical, geochemical, and bio-optical fields influenced by pulsed river discharge to understand potential 3-D pathways of ODS to the coast and mechanisms for enhanced interactions of ODS with plankton and suspended sediment.

Glider deployed as part of the CONsortium for oil spill exposure pathways in COastal River-Dominated Ecosystems (CONCORDE). The goal of the project is to use a combination of observations and numerical modeling to Characterize the complex 4D physical, geochemical, and bio-optical fields influenced by pulsed river discharge to understand potential 3-D pathways of ODS to the coast and mechanisms for enhanced interactions of ODS with plankton and suspended sediment.

Glider deployed as part of the CONsortium for oil spill exposure pathways in COastal River-Dominated Ecosystems (CONCORDE). The goal of the project is to use a combination of observations and numerical modeling to Characterize the complex 4D physical, geochemical, and bio-optical fields influenced by pulsed river discharge to understand potential 3-D pathways of ODS to the coast and mechanisms for enhanced interactions of ODS with plankton and suspended sediment.

Deployment of a Slocum glider to perform surveys of dissolved oxygen concentrations in the shallow coastal waters of New Jersey. This dataset currently provides only CTD measurements. Additional parameters, including oxygen and optical measurements, will be provided once the appropriate quality assessment algorithms have been applied.