Abstract
The retrieval of sun-induced chlorophyll fluorescence is greatly beneficial to studies of marine phytoplankton biomass, physiology, and composition, and is required for user applications and services. Customarily phytoplankton chlorophyll fluorescence is determined from satellite measurements through a fluorescence line-height algorithm using three bands around 680 nm. We propose here a modified retrieval, making use of all available bands in the relevant wavelength range, with the goal to improve the effectiveness of the algorithm in optically complex waters. For the Ocean and Land Colour Instrument (OLCI), we quantify a Fluorescence Peak Height by fitting a Gaussian function and related terms to the top-of-atmosphere reflectance bands between 650 and 750 nm. This algorithm retrieves, what we call Fluorescence Peak Height by fitting a Gaussian function upon other terms to top-of-atmosphere reflectance bands between 650 and 750 nm. This approach is applicable to Level-1 and Level-2 data. We find a good correlation of the retrieved fluorescence product to global in-situ chlorophyll measurements, as well as a consistent relation between chlorophyll concentration and fluorescence from radiative transfer modelling and OLCI/in-situ comparison. Evidence suggests, the algorithm is applicable to complex waters without needing an atmospheric correction and vicarious calibration, and features an inherent correction of small spectral shifts, as required for OLCI measurements.
Highlights
Chlorophyll fluorescence is light re-emitted by chlorophyll molecules when returning from excited to non-excited states [1]
We find a good correlation of the retrieved fluorescence product to global in-situ chlorophyll measurements, as well as a consistent relation between chlorophyll concentration and fluorescence from radiative transfer modelling and Ocean and Land Colour Instrument (OLCI)/in-situ comparison
The chlorophyll retrieval is customarily based on the detection of the chlorophyll absorption signal [4,5,6] which can be gained through the ratio of the chlorophyll fluorescence to the absorption signal [7]
Summary
Chlorophyll fluorescence is light re-emitted by chlorophyll molecules when returning from excited to non-excited states [1]. Quantification of solar-induced phytoplankton fluorescence has two main advantages in marine bio-geochemistry applications [2,3]. These are: (1) the improvement of the chlorophyll retrieval, and (2) additional information on phytoplankton physiological state, biomass and maximum layer depth. Sensed Fluorescence Line Height (FLH, see Equation (1)) can better reveal blooms in coastal areas than chlorophyll retrievals based on the ratios of water-leaving radiances in the blue and green spectral range (440–560 nm) by allowing better differentiation of phytoplankton chlorophyll-a concentrations from suspended sediments and colored dissolved organic matter (CDOM) [8]. A fluorescence retrieval could be of particular value in optically complex waters, which are independently influenced by CDOM, phytoplankton, and suspended sediments
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