Coastal and ocean acidification has the potential to cause significant environmental and
societal impacts. Monitoring carbonate chemistry parameters over spatial and temporal …

We report a new, autonomous Lab-on-Chip (LOC) microfluidic pH sensor with a 6000 m
depth capability, ten times the depth capability of the state of the art autonomous …

Ion‐sensitive field effect transistor‐based pH sensors have been shown to perform well in
high frequency and long‐term ocean sampling regimes. The Honeywell Durafet is widely …

We introduce for the first time a new product line able to make high accuracy measurements
of a number of water chemistry parameters in situ: ie, submerged in the environment …

Observations of the marine CO 2 system are important for understanding ocean acidification,
air-sea CO 2 fluxes and the marine carbon cycle in general. A variety of autonomous in situ …

Measuring pH in glacial meltwaters is challenging, because they are cold, remote, subject to
freeze‐thaw cycles and have low ionic strength. Traditional methods often perform poorly …

The commercially available Sea-Bird SeaFET™ provides an accessible way for a broad
community of researchers to study ocean acidification and obtain robust measurements of …

Acidification in nearshore waters is influenced by a multitude of drivers that shape the
dynamics of pH and carbonate chemistry variability on diurnal, seasonal, and yearly time …

The use of Durafet-based sensors has proliferated in recent years, but their performance in
estuarine waters (salinity< 20) where rapid changes in temperature and salinity are …

Studying carbon dioxide in the ocean helps to understand how the ocean will be impacted
by climate change and respond to increasing fossil fuel emissions. The marine carbonate …