Characterizing the Absorption Properties for Remote Sensing of Three Small Optically-Diverse South African Reservoirs

Characterizing the specific inherent optical properties (SIOPs) of water constituents is fundamental to remote sensing applications. Therefore, this paper presents the absorption properties of phytoplankton, gelbstoff and tripton for three small, optically-diverse South African inland waters. The three reservoirs, Hartbeespoort, Loskop and Theewaterskloof, are challenging for remote sensing, due to differences in phytoplankton assemblage and the considerable range of constituent concentrations. Relationships between the absorption properties and biogeophysical parameters, chlorophyll-a (chl-a), TChl (chl-a plus phaeopigments), seston, minerals and tripton, are established. The value determined for the mass-specific tripton absorption coefficient at 442 nm, a∗ (442), ranges from 0.024 to 0.263 m2·g−1. The value of the TChl-specific phytoplankton absorption coefficient (a∗ ) was strongly influenced by phytoplankton species, size, accessory pigmentation and biomass. a∗ (440) ranged from 0.056 to 0.018 m2·mg−1 in oligotrophic to hypertrophic waters. The positive relationship between cell size and trophic state observed in open ocean waters was violated by significant small cyanobacterial populations. The phycocyanin-specific phytoplankton absorption at 620 nm, a∗ (620), was determined as 0.007 m2·g−1 in a M. aeruginosa bloom. Chl-a was a better indicator of phytoplankton biomass than phycocyanin (PC) in surface scums, due to reduced accessory pigment production. Absorption budgets demonstrate that monospecific blooms of M. aeruginosa and C. hirundinella may be treated as “cultures”, removing some complexities for remote sensing applications. These results contribute toward a better understanding of IOPs and remote sensing applications in hypertrophic inland waters. However, the majority of the water is optically complex, requiring the usage of all the SIOPs derived here for remote sensing applications. The SIOPs may be used for developing remote sensing algorithms for the detection of biogeophysical parameters, including chl-a, suspended matter, tripton and gelbstoff, and in advanced remote sensing studies for phytoplankton type detection.

[1]  Arnold G. Dekker,et al.  Simulation of AVIRIS Sensitivity for Detecting Chlorophyll over Coastal and Inland Waters , 1998 .

[2]  R. Sommaruga,et al.  The significance of autotrophic and heterotrophic picoplankton in hypertrophic ecosystems , 1997 .

[3]  U. Hansen,et al.  Spectral fluorescence of chlorophyll and phycobilins as an in-situ tool of phytoplankton analysis - models, algorithms and instruments , 2003 .

[4]  Vittorio E. Brando,et al.  Assessment of water quality in Lake Garda (Italy) using Hyperion , 2007 .

[5]  Emmanuel Boss,et al.  Role of iron and organic carbon in mass‐specific light absorption by particulate matter from Louisiana coastal waters , 2012 .

[6]  C. van Ginkel,et al.  Temporal trends in total phosphorus, temperature, oxygen, chlorophyll a and phytoplankton populations in Hartbeespoort Dam and Roodeplaat Dam, South Africa, between 1980 and 2000 , 2007 .

[7]  Steven W. Effler,et al.  Light absorbing components in the Finger Lakes of New York. , 2009 .

[8]  Y. X. Li,et al.  A simple method for extracting C-phycocyanin from Spirulina platensis using Klebsiella pneumoniae , 2007, Applied Microbiology and Biotechnology.

[9]  D. R. Heinle,et al.  A comparison by size class and volume of detritus versus phytoplankton in Chesapeake Bay , 1978 .

[10]  Machteld Rijkeboer,et al.  Coupling of phytoplankton and detritus in a shallow, eutrophic lake (Lake Loosdrecht, The Netherlands) , 1992, Hydrobiologia.

[11]  M. Guirlet,et al.  Assimilation of Odin/SMR O3 and N2O measurements in a three‐dimensional chemistry transport model , 2004 .

[12]  H. Siegelman,et al.  Light Intensity Adaptation and Phycobilisome Composition of Microcystis aeruginosa. , 1985, Plant physiology.

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

[14]  Stefan G. H. Simis,et al.  In vivo mass‐specific absorption spectra of phycobilipigments through selective bleaching , 2012 .

[15]  T. Lauridsen,et al.  Identification and quantification of phytoplankton groups in lakes using new pigment ratios – a comparison between pigment analysis by HPLC and microscopy , 2006 .

[16]  Isabelle Laurion,et al.  Distribution of mycosporine-like amino acids and photoprotective carotenoids among freshwater phytoplankton assemblages , 2002 .

[17]  Marcel Babin,et al.  Light absorption properties and absorption budget of Southeast Pacific waters , 2010 .

[18]  B. Osborne,et al.  Light and Photosynthesis in Aquatic Ecosystems. , 1985 .

[19]  Richard D. Robarts,et al.  The influence of temperature and light on the upper limit of Microcystis aeruginosa production in a hypertrophic reservoir , 1992 .

[20]  J. U. Grobbelaar,et al.  Extraction of chlorophyll a from freshwater phytoplankton for spectrophotometric analysis , 1984, Hydrobiologia.

[21]  Blanka Desortová,et al.  Relationship between Chlorophyll-α Concentration and Phytoplankton Biomass in Several Reservoirs in Czechoslovakia , 1981 .

[22]  A. Botha,et al.  Responses of phytoplankton upon exposure to a mixture of acid mine drainage and high levels of nutrient pollution in Lake Loskop, South Africa. , 2010, Ecotoxicology and environmental safety.

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

[24]  Stelvio Tassan,et al.  A method for the experimental determination of light absorption by aquatic heterotrophic bacteria , 1998 .

[25]  Antonio Ruiz-Verdú,et al.  An evaluation of algorithms for the remote sensing of cyanobacterial biomass , 2008 .

[26]  Richard D. Robarts,et al.  Interannual phytoplankton dynamics of a hypertrophic African lake , 1996 .

[27]  M. Matthews,et al.  Using a two-layered sphere model to investigate the impact of gas vacuoles on the inherent optical properties of M . aeruginosa , 2013 .

[28]  Collin S. Roesler Theoretical and experimental approaches to improve the accuracy of particulate absorption coefficients derived from the quantitative filter technique , 1998 .

[29]  D. Lindenmayer,et al.  Can Individual and Social Patterns of Resource Use Buffer Animal Populations against Resource Decline? , 2013, PloS one.

[30]  Glenn CampbellStuart The specific inherent optical properties of three sub-tropical and tropical water reservoirs in Queensland, Australia , 2011 .

[31]  Dariusz Stramski,et al.  Variations in the mass‐specific absorption coefficient of mineral particles suspended in water , 2004 .

[32]  S. Peters,et al.  Comparison of remote sensing data, model results and in situ data for total suspended matter (TSM) in the southern Frisian lakes. , 2001, The Science of the total environment.

[33]  P. D. Wragg,et al.  Recent blooms of the dinoflagellate Ceratium in Albert Falls Dam (KZN): history, causes, spatial features and impacts on a reservoir ecosystem and its zooplankton , 2009 .

[34]  Stuart R. Phinn,et al.  The specific inherent optical properties of three sub-tropical and tropical water reservoirs in Queensland, Australia , 2010, Hydrobiologia.

[35]  C. V. Ginkel,et al.  A Ceratium hirundinella (O.F. Müller) bloom in Hartbeespoort Dam, South Africa , 2004 .

[36]  Wen Yuanhua CONTRIBUTION OF BACTERIOPLANKTON, PHYTOPLANKTON, ZOOPLANKTON AND DETRITUS TO ORGANIC SESTON CARBON LOAD IN A CHANGJIANG FLOODPLAIN LAKE (CHINA) , 1992 .

[37]  Kazuo Oki,et al.  Why is the Ratio of Reflectivity Effective for Chlorophyll Estimation in the Lake Water? , 2010, Remote. Sens..

[38]  Stelvio Tassan,et al.  A METHOD USING CHEMICAL OXIDATION TO REMOVE LIGHT ABSORPTION BY PHYTOPLANKTON PIGMENTS , 1999 .

[39]  Warwick F. Vincent,et al.  Relationships between spectral optical properties and optically active substances in a clear oligotrophic lake , 2004 .

[40]  P. Fay,et al.  Underwater light climate and the growth and pigmentation of planktonic blue-green algae (Cyanobacteria) II. The influence of light quality , 1986, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[41]  李幼升,et al.  Ph , 1989 .

[42]  C. Reynolds The Ecology of Phytoplankton , 2006 .

[43]  Guangwei Zhu,et al.  Measured and numerically partitioned phytoplankton spectral absorption coefficients in inland waters , 2008 .

[44]  F. H. Farmer,et al.  Extraction, identification, and quantitation of phycobiliprotein pigments from phototrophic plankton , 1984 .

[45]  John A. Berges,et al.  Ratios, regression statistics, and “spurious” correlations , 1997 .

[46]  H. Claustre,et al.  Variability in the chlorophyll‐specific absorption coefficients of natural phytoplankton: Analysis and parameterization , 1995 .

[47]  Jun Zhao,et al.  Inherent and apparent optical properties of the complex estuarine waters of Tampa Bay: What controls light? , 2013 .

[48]  Xin Wang,et al.  Bio‐optical properties and estimation of the optically active substances in Lake Tianmuhu in summer , 2009 .

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

[50]  Lisa R. Moore,et al.  Determination of spectral absorption coefficients of particles, dissolved material and phytoplankton for discrete water samples , 2000 .

[51]  Vittorio E. Brando,et al.  Bio‐optical variability of the absorption and scattering properties of the Queensland inshore and reef waters, Australia , 2009 .

[52]  M. Matthews,et al.  An algorithm for detecting trophic status (chlorophyll-a), cyanobacterial-dominance, surface scums and floating vegetation in inland and coastal waters , 2012 .

[53]  Hee-Mock Oh,et al.  Alternative alert system for cyanobacterial bloom, using phycocyanin as a level determinant. , 2007, Journal of microbiology.

[54]  Gokare A. Ravishankar,et al.  Phycocyanin from Spirulina sp: influence of processing of biomass on phycocyanin yield, analysis of efficacy of extraction methods and stability studies on phycocyanin , 1999 .

[55]  L. Prieur,et al.  Absorption by dissolved organic matter of the sea (yellow substance) in the UV and visible domains1 , 1981 .

[56]  D. F. Toerien,et al.  THE LIMNOLOGY OF SOME SOUTH AFRICAN IMPOUNDMENTS I. THE PHYSICO-CHEMICAL LIMNOLOGY OF HARTBEESPOORT DAM , 1977 .

[57]  C. A. Bruwer,et al.  WATER TRANSPARENCY CHARACTERISTICS OF SOUTH AFRICAN IMPOUNDMENTS , 1980 .

[58]  Pertti J Viskari,et al.  Rapid extraction of phycobiliproteins from cultured cyanobacteria samples. , 2003, Analytical biochemistry.

[59]  A. Grossman,et al.  A response regulator of cyanobacteria integrates diverse environmental signals and is critical for survival under extreme conditions. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[60]  Stewart Bernard,et al.  Using a two-layered sphere model to investigate the impact of gas vacuoles on the inherent optical properties of Microcystis aeruginosa , 2013 .

[61]  Stefan G. H. Simis,et al.  Remote sensing of the cyanobacterial pigment phycocyanin in turbid inland water , 2005 .

[62]  Richard D. Robarts,et al.  Microcystis Aeruginosa and Underwater Light Attenuation in a Hypertrophic Lake (Hartbeespoort Dam, South Africa) , 1984 .

[63]  T. E. Cloete,et al.  An overview of toxic freshwater cyanobacteria in South Africa with special reference to risk, impact and detection by molecular marker tools , 2006 .

[64]  Jacqueline Dabrowski,et al.  Water quality, metal bioaccumulation and parasite communities of Oreochromis mossambicus in Loskop Dam, Mpumalanga, South Africa , 2012 .

[65]  William G. Booty,et al.  Spectral absorption properties of dissolved and particulate matter in Lake Erie , 2008 .

[66]  Philippe Juneau,et al.  Comparison of Photoacclimation in Twelve Freshwater Photoautotrophs (Chlorophyte, Bacillaryophyte, Cryptophyte and Cyanophyte) Isolated from a Natural Community , 2013, PloS one.

[67]  Prieur,et al.  Analysis of variations in ocean color’ , 2000 .

[68]  Bas W Ibelings,et al.  Acclimation of photosystem II in a cyanobacterium and a eukaryotic green alga to high and fluctuating photosynthetic photon flux densities, simulating light regimes induced by mixing in lakes. , 1994, The New phytologist.

[69]  Tamar Zohary Hyperscums of the cyanobacterium Microcystis aeruginosa in a hypertrophic lake (Hartbeespoort Dam, South Africa) , 1985 .

[70]  Junsheng Li,et al.  Modeling Remote-Sensing Reflectance and Retrieving Chlorophyll-a Concentration in Extremely Turbid Case-2 Waters (Lake Taihu, China) , 2009, IEEE Transactions on Geoscience and Remote Sensing.

[71]  Antonio Ruiz-Verdú,et al.  Influence of phytoplankton pigment composition on remote sensing of cyanobacterial biomass , 2007 .

[72]  Dariusz Stramski,et al.  Variations in the optical properties of terrigenous mineral‐rich particulate matter suspended in seawater , 2007 .

[73]  Lawrence Bogorad,et al.  COMPLEMENTARY CHROMATIC ADAPTATION IN A FILAMENTOUS BLUE-GREEN ALGA , 1973, The Journal of cell biology.