Hyperspectral and multispectral ocean color inversions to detect Phaeocystis globosa blooms in coastal waters

Identification of phytoplankton groups from space is essential to map and monitor algal blooms in coastal waters, but remains a challenge due to the presence of suspended sediments and dissolved organic matter which interfere with phytoplankton signal. On the basis of field measurements of remote sensing reflectance (Rrs(λ)), bio-optical parameters, and phytoplankton cells enumerations, we assess the feasibility of using multispectral and hyperspectral approaches for detecting spring blooms of Phaeocystis globosa (P. globosa). The two reflectance ratios (Rrs(490) /Rrs(510) and Rrs(442.5) /Rrs(490)), used in the multispectral inversion, suggest that detection of P. globosa blooms are possible from current ocean color sensors. The effects of chlorophyll concentration, colored dissolved organic matter (CDOM), and particulate matter composition on the performance of this multispectral approach are investigated via sensitivity analysis. This analysis indicates that the development of a remote sensing algorithm, based on the values of these two ratios, should include information about CDOM concentration. The hyperspectral inversion is based on the analysis of the second derivative of Rrs(λ) (dλ2 Rrs). Two criteria, based on the position of the maxima and minima of dλ2Rrs, are established to discriminate the P. globosa blooms from diatoms blooms. We show that the position of these extremes is related to the specific absorption spectrum of P. globosa and is significantly correlated with the relative biomass of P. globosa. This result confirms the advantage of a hyperspectral over multispectral inversion for species identification and enumeration from satellite observations of ocean color. Copyright 2008 by the American Geophysical Union.

[1]  Dariusz Stramski,et al.  Light scattering properties of marine particles in coastal and open ocean waters as related to the particle mass concentration , 2003 .

[2]  Paul J. Curran,et al.  Derivative Reflectance Spectroscopy to Estimate Suspended Sediment Concentration , 1992 .

[3]  Richard P. Santer,et al.  Bio-optical Properties of Coastal Waters in the Eastern English Channel , 2007 .

[4]  D. Siegel,et al.  An improved bio‐optical model for the remote sensing of Trichodesmium spp. blooms , 2005 .

[5]  C. Davis,et al.  Derivative analysis of absorption features in hyperspectral remote sensing data of carbonate sediments. , 2002, Optics express.

[6]  François-Marie Bréon,et al.  Remote sensing of phytoplankton groups in case 1 waters from global SeaWiFS imagery , 2005 .

[7]  Susan Walsh,et al.  Ocean color: Availability of the global data set , 1989 .

[8]  C. Hamm,et al.  Phaeocystis globosa (Prymnesiophyceae) colonies: hollow structures built with small amounts of polysaccharides , 1997 .

[9]  Oscar Schofield,et al.  Detection of harmful algal blooms using photopigments and absorption signatures: A case study of the Florida red tide dinoflagellate, Gymnodinium breve , 1997 .

[10]  Christiane Lancelot,et al.  Phaeocystis blooms in the global ocean and their controlling mechanisms: a review , 2005 .

[11]  Ken Caldeira,et al.  Seasonal rhythms of net primary production and particulate organic carbon flux to depth describe the efficiency of biological pump in the global ocean , 2007 .

[12]  C. Hamm Architecture, ecology and biogeochemistry of Phaeocystis colonies , 2000 .

[13]  Annick Bricaud,et al.  Natural variability of phytoplanktonic absorption in oceanic waters: Influence of the size structure of algal populations , 2004 .

[14]  T. Platt,et al.  Remote sensing of phytoplankton pigments: A comparison of empirical and theoretical approaches , 2001 .

[15]  Fuan Tsai,et al.  Derivative Analysis of Hyperspectral Data , 1998 .

[16]  D. Vaulot,et al.  The life cycle of Phaeocystis (Prymnesiophycaea): evidence and hypotheses , 1994 .

[17]  L. Artigas,et al.  The colonization of two Phaeocystis species ( Prymnesiophyceae ) by pennate diatoms and other protists: a significant contribution to colony biomass , 2007 .

[18]  W. Vyverman,et al.  Spatial variation in phytoplankton dynamics in the Belgian coastal zone of the North Sea studied by microscopy, HPLC-CHEMTAX and underway fluorescence recordings , 2006 .

[19]  R. Arnone,et al.  Deriving inherent optical properties from water color: a multiband quasi-analytical algorithm for optically deep waters. , 2002, Applied optics.

[20]  X. Irigoien,et al.  Selective feeding on natural phytoplankton by Calanus finmarchicus before, during, and after the 1997 spring bloom in the Norwegian Sea , 1999 .

[21]  H. Loisel,et al.  Variability and classification of remote sensing reflectance spectra in the eastern English Channel and southern North Sea , 2007 .

[22]  Richard P. Stumpf,et al.  MONITORING KARENIA BREVIS BLOOMS IN THE GULF OF MEXICO USING SATELLITE OCEAN COLOR IMAGERY AND OTHER DATA , 2003 .

[23]  J. Cullen,et al.  Detection of Karenia mikimotoi by spectral absorption signatures , 2003 .

[24]  R. Leathers,et al.  Self-shading correction for oceanographic upwelling radiometers. , 2004, Optics express.

[25]  S. Gibb,et al.  Intra-class variability in the carbon, pigment and biomineral content of prymnesiophytes and diatoms , 2000 .

[26]  E. Fry,et al.  Absorption spectrum (380-700 nm) of pure water. II. Integrating cavity measurements. , 1997, Applied optics.

[27]  T. Platt,et al.  Discrimination of diatoms from other phytoplankton using ocean-colour data , 2004 .

[28]  Dariusz Stramski,et al.  Spectral dependency of optical backscattering by marine particles from satellite remote sensing of the global ocean , 2006 .

[29]  T. Platt,et al.  Bio-optical characteristics of diatom and prymnesiophyte populations in the Labrador Sea , 2000 .

[30]  B. Lubac,et al.  Challenges to identify phytoplankton species in coastal waters by remote sensing , 2005, SPIE Optics + Photonics.

[31]  T. Smyth,et al.  Optical modeling and measurements of a coccolithophore bloom. , 2002, Applied optics.

[32]  E. Carpenter,et al.  Detecting Trichodesmium blooms in SeaWiFS imagery , 2001 .

[33]  John J. Cullen,et al.  Optical detection and assessment of algal blooms , 1997 .

[34]  J. Kirk,et al.  A THEORETICAL ANALYSIS OF THE CONTRIBUTION OF ALGAL CELLS TO THE ATTENUATION OF LIGHT WITHIN NATURAL WATERS II. SPHERICAL CELLS , 1975 .

[35]  C. Lancelot,et al.  19′-hexanoyloxyfucoxanthin may not be the appropriate pigment to trace occurrence and fate of Phaeocystis: the case of P. globosa in Belgian coastal waters , 2004 .

[36]  François-Marie Bréon,et al.  A species-dependent bio-optical model of case I waters for global ocean color processing , 2006 .

[37]  Dongyan Liu,et al.  Geometric models for calculating cell biovolume and surface area for phytoplankton , 2003 .

[38]  Susanne Menden-Deuer,et al.  Carbon to volume relationships for dinoflagellates, diatoms, and other protist plankton , 2000 .

[39]  A. Bricaud,et al.  Theoretical results concerning light absorption in a discrete medium, and application to specific absorption of phytoplankton , 1981 .

[40]  M. Veldhuis,et al.  Bloom dynamics and biological control of a high biomass HAB species in European coastal waters: A Phaeocystis case study , 2005 .

[41]  Jean-François Berthon,et al.  Investigation of the optical backscattering to scattering ratio of marine particles in relation to their biogeochemical composition in the eastern English Channel and southern North Sea , 2007 .

[42]  William Philpot,et al.  The derivative ratio algorithm: avoiding atmospheric effects in remote sensing , 1991, IEEE Trans. Geosci. Remote. Sens..

[43]  S. W. Jeffrey,et al.  Introduction to marine phytoplankton and their pigment signatures , 1997 .

[44]  L. Prieur,et al.  Analysis of variations in ocean color1 , 1977 .

[45]  Zhongping Lee,et al.  Use of hyperspectral remote sensing reflectance for detection and assessment of the harmful alga, Karenia brevis. , 2006, Applied optics.

[46]  Dale A. Kiefer,et al.  In-vivo absorption properties of algal pigments , 1990, Defense, Security, and Sensing.

[47]  J. Dungan,et al.  Reflectance spectroscopy of fresh whole leaves for the estimation of chemical concentration , 1992 .

[48]  Dariusz Stramski,et al.  Variations in the light absorption coefficients of phytoplankton, nonalgal particles, and dissolved organic matter in coastal waters around Europe , 2003 .

[49]  B. Sautour,et al.  Annual variations of phytoplankton biomass in the Eastern English Channel: comparison by pigment signatures and microscopic counts , 2000 .

[50]  Margareth N. Kyewalyanga,et al.  Temperature as indicator of optical properties and community structure of marine phytoplankton: implications for remote sensing , 2003 .

[51]  L. Edler,et al.  Recommendations on methods for marine biological studies in the Baltic Sea. Phytoplankton and chlorophyll , 1979 .

[52]  M. Moline,et al.  Optical discrimination of a phytoplankton species in natural mixed populations , 2000 .

[53]  Andrew J. Watson,et al.  Ecosystem dynamics based on plankton functional types for global ocean biogeochemistry models , 2005 .

[54]  Richard P. Stumpf,et al.  Evaluation of the use of SeaWiFS imagery for detecting Karenia brevis harmful algal blooms in the eastern Gulf of Mexico , 2004 .

[55]  Xiaoping Zhou,et al.  Marine ecology: Spring algal bloom and larval fish survival , 2003, Nature.

[56]  Kevin Ruddick,et al.  Optical properties of algal blooms in an eutrophicated coastal area and its relevance to remote sensing , 2005, SPIE Optics + Photonics.

[57]  G. Johnsen,et al.  In vivo absorption characteristics in 10 classes of bloom-forming phytoplankton: taxonomic characteristics and responses to photoadaptation by means of discriminant and HPLC analysis , 1994 .

[58]  L. Schlüter,et al.  The use of phytoplankton pigments for identifying and quantifying phytoplankton groups in coastal areas: testing the influence of light and nutrients on pigment/chlorophyll a ratios , 2000 .