Phytoplankton photocompensation from space‐based fluorescence measurements

Recent satellite‐derived observations linked global scale phytoplankton fluorescence variability with iron stress and hinted at photophysiological responses associated with changing light levels. These photocompensation reactions, the sum of photoacclimation and photoadaptation, were examined with climatological data for the Gulf of Maine. Significant seasonal variability was observed in the fluorescence quantum yield that was unrelated to patterns of biomass. Up to 89% of the variability in the fluorescence quantum yield was explained by a physiology‐based photocompensation model. Spatial variability in seasonal patterns was associated with differing hydrodynamic regimes. This variability in the quantum yield demonstrates that satellite‐based fluorescence is inappropriate for phytoplankton biomass determinations. More importantly, the work presented here provides the modeling foundation for fluorescence‐based investigations of temporal and spatial variability in phytoplankton physiology associated with growth irradiance. These space‐based physiological observations have the potential to decrease uncertainties in future ocean color derived primary productivity estimates.

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