Dependence between the quantum yield of chlorophyll a fluorescence in marine phytoplankton and trophicity in low irradiance level

• Autorzy: Ostrowska M.
• Języki publikacji: EN

Abstrakty

EN

The paper presents the dependence of relative fluorescence quantum yield of marine phytoplankton on trophicity (as a measure of trophicity the chlorophyll a concentration was assumed). The dependence was worked out using the following empirical data from different regions of Southern Baltic: artificially excited phytoplankton fluorescence measured with BBE Moldaenke FluoroProbe and phytoplankton light absorption coefficient measured with spectrophotometer. The statistical analyzes allow establishing mathematical expression describing relation between fluorescence quantum yield and chlorophyll a concentration in sea water. This result can be useful in the future in the modeling of fluorescence quantum yield as a function of environmental factors.

Słowa kluczowe

EN

marine optics; optical measurements in the photobiology; quantum yield

• Wydawca: Oficyna Wydawnicza Politechniki Wrocławskiej
• Czasopismo: Optica Applicata
• Rocznik: 2011
• Tom: Vol. 41, nr 3
• Strony: 567--577
• Opis fizyczny: Bibliogr. 31 poz.

Twórcy

autor

Ostrowska M.

• Institute of Oceanology, Polish Academy of Sciences, Powstańców Warszawy 55, 81-712 Sopot, Poland

Bibliografia

• [1] FALKOWSKI P.G., KIEFER D.A., Chlorophyll a fluorescence in phytoplankton: Relationship to photosynthesis and biomass, Journal of Plankton Research 7(5), 1985, pp. 715–731.
• [2] FALKOWSKI P.G., KOLBER Z., Phytoplankton photosynthesis in the Atlantic Ocean as measured from a submersible pump and probe fluorometer in situ, [In] Current Research in Photosynthesis, Baltscheffsky M. [Ed.], Kulver, 1990, pp. 923–926.
• [3] KOLBER Z., FALKOWSKI P.G., Use of active fluorescence to estimate phytoplankton photosynthesis in situ, Limnology and Oceanography 38(8), 1993, pp. 1646–1665.
• [4] FALKOWSKI P.G., WYMAN K., LEY A.C., MAUZERALL D., Relationship of steady-state photosynthesis to fluorescence in eukaryotic algae, Biochimica et Biophysica Acta 849, 1986, pp. 183–192.
• [5] HUOT Y., BROWN C.A., CULLEN J.J., Retrieval of phytoplankton biomass from simultaneous inversion of reflectance, the diffuse attenuation coefficient and Sun-induced fluoresence in coastal waters, Journal of Geophysical Research 112, 2007, p. C06013.
• [6] MATORIN D.N., VASILEV I.R., VENEDIKTOV P.S., ZAKHARKOV S.P., Metod nepreryvnego zondirovaniya aktyvnogo fitoplanktona v vodoemakh putem registratsii zamedlennoy fluorestsentsii, Gidrombiol. zh., Kiyev, 22(2), 1986, pp. 87–89.
• [7] MATORIN D.N., VENEDIKTOV P.S., KONEV YU. N., KAZEMIRKO YU. V., RUBIN A.B., Application of a double-flash, impulse, submersible fluorimeter in the determination of photosynthetic activity of natural phytoplankton, Transactions (Doklady) of the Russian Academy of Sciences – Earth Science Sections 350(7), 1996, pp. 1159–1161.
• [8] MATORIN D.N., VENEDIKTOV P.S., Zamedlennaya fluorestsentsiya i yeyo ispolzovaniye dlya otsenki sostoyaniya rastitelnogo organizma, Izvestiya Akademii Nauk SSSR – Seriya Biologicheskaya 4, 1985, pp. 508–520.
• [9] MATORIN D.N., VENEDIKTOV P.S., Luminestsentsiya Khlorofilla v Kulturakh Mikrovodorosley i Prirodnykh Populyatsiyakh Fitoplanktona, Itogi Nauki Tekh., Ser. Biofiz., Moscow VINITI, Vol. 40, 1990, pp. 49–100.
• [10] OSTROWSKA M., MAJCHROWSKI R., MATORIN D.N., WOŹNIAK B., Variability of the specific fluorescence of chlorophyll in the ocean. Part 1. Theory of classical ‘in situ’ chlorophyll fluorometry, Oceanologia 42(2), 2000, pp. 203–219.
• [11] OSTROWSKA M., MATORIN D.N., FICEK D., Variability of the specific fluorescence of chlorophyll in the ocean. Part 2. Fluorometric method of chlorophyll a determination, Oceanologia 42(2), 2000, pp. 221–229.
• [12] POGOSYAN S.I., SIVCHENKO M.A., MAXIMOV V.M., OSTROWSKA M., Physiological heterogenity of an algal population: Classification of ‘Scenedesmus quadricauda’ cenobia by the features of their photosynthetic apparatus, Oceanologia 39(2), 1997, pp. 163–175.
• [13] BABIN M., THERRIAULT J.C., LEGENDRE L., NIEKE B., REUTER R., CONDAL A., Relationship between the maximum quantum yield of carbon fixation and the minimum quantum yield of chlorophyll a in vivo fluorescence in the Gulf of St. Lawrence, Limnology and Oceanography 40(5), 1995, pp. 956–968.
• [14] BABIN M., MOREL A., GENTILI B., Remote sensing of sea surface Sun-induced chlorophyll fluorescence: Consequences of natural variations in the optical characteristics of phytoplankton and the quantum yield of chlorophyll a fluorescence, International Journal of Remote Sensing 17(12), 1996, pp. 2417–2448.
• [15] OSTROWSKA M., DARECKI M., WOŹNIAK B., An attempt to use measurements of sun-induced chlorophyll fluorescence to estimate chlorophyll a concentration in the Baltic Sea, Proceedings of SPIE 3222, 1997, pp. 528–537.
• [16] MARITORENA S., MOREL A., GENTILI B., Determination of the fluorescence quantum yield by oceanic phytoplankton in their natural habitat, Applied Optics 39(36), 2000, pp. 6725–6737.
• [17] MORRISON J.R., In situ determination of quantum yield of phytoplankton chlorophyll a fluorescence: A simple algorithm, observations, and a model, Limnology and Oceanography 48(2), 2003, pp. 618–631.
• [18] HUOT Y., BROWN C.A., CULLEN J.J., New algorithms for MODIS sun-induced chlorophyll fluorescence and a comparison with present data products, Limnology and Oceanography: Methods 3(2), 2005, pp. 108–130.
• [19] SCHALLENBERG C., LEWIS M.R., KELLEY D.E, CULLEN J.J., Inferred influence of nutrient availability on the relationship between Sun-induced chlorophyll fluorescence and imcident irradiance in the Bering Sea, Journal of Geophysical Research 113, 2008, p. C07046.
• [20] OSTROWSKA M., The application of fluorescence methods to the study of marine photosynthesis, Diss. and monogr., IO PAS, Sopot, 15, 2001, p. 194, (in Polish).
• [21] WOŹNIAK B., FICEK D., OSTROWSKA M., MAJCHROWSKI R., DERA J., Quantum yield of photosynthesis in the Baltic: A new mathematical expression for remote sensing applications, Oceanologia 49(4), 2007, pp. 527–542
• [22] BEUTLER M., WILTSHIRE K.H., MEYER B., MOLDAENKE C., LÜRING C., MEYERHÖFER M., HANSEN U.P., DAU H., A fluorometric method for the differentiation of algal populations in vivo and in situ, Photosynthesis Research 72(1), 2002, pp. 39–53.
• [23] WOŹNIAK B., DERA J., FICEK D., OSTROWSKA M., MAJCHROWSKI R., Dependence of the photosynthesis quantum yield in oceans on environmental factors, Oceanologia 44(4), 2002, pp. 439–459.
• [24] WOŹNIAK B., DERA J., FICEK D., OSTROWSKA M., MAJCHROWSKI R., KACZMAREK S., KUZIO M., The current bio-optical study of marine phytoplankon, Optica Applicata 32(4), 2002, pp. 731–747.
• [25] WOŹNIAK B., DERA J., FICEK D., MAJCHROWSKI R., OSTROWSKA M., KACZMAREK S., Modelling light and photosynthesis in the marine environment, Oceanologia 45(2), 2003, pp. 171–245.
• [26] WOŹNIAK B., DERA J., KOBLENTZ-MISHKE O.I., Bio-optical relationships for estimating primary production in the Ocean, Oceanologia 33, 1992, pp. 5–38.
• [27] EDLER L. [Ed.], Recommendations for Marine Biological Studies in the Baltic Sea, Phytoplankton and Chlorophyll, The Baltic Marine Biologists, Publ. 5, 1979.
• [28] STRICKLAND J.D.H., PARSONS T.R., A practical handbook of seawater analysis. Pigment analysis, Bulletin of the Fisheries Research Board of Canada 167, 1968, pp. 1–311.
• [29] TASSAN S., FERRARI G.M., An alternative approach to absorption measurements of aquatic particles retained on fliters, Limnology and Oceanography 40(8), 1995, pp. 1358–1368.
• [30] TASSAN S., FERRARI G.M., A sensitivity analysis of the ‘transmittance–reflectance’ method for measuring light absorption by aquatic particles, Journal of Plankton Research 24(8), 2002, pp. 757–774.
• [31] WOŹNIAK B., DERA J., Light Absorption in Sea Water, Atmospheric and Oceanographic Sciences Library, Vol. 33, Springer, New York, 2007.