e nonphotochemical radiationless dissipation) by phytoplankton p

e. nonphotochemical radiationless dissipation) by phytoplankton pigments in order to obtain a full description of the dependences of the deactivation of phytoplankton pigment excitation energy on environmental conditions in the sea. The end result can be regarded as satisfactory, given the current state of knowledge of the functioning of plant communities in the sea. A model was derived (see Table 1) enabling quantum yields to be estimated from values of three basic environmental factors governing the growth of phytoplankton in the sea,

i.e. basin trophicity Ca(0), and the downward irradiance www.selleckchem.com/products/abt-199.html P AR(z) and the water temperature temp(z) at the study site. The model should be regarded as a preliminary version, for two reasons: 1. In view of the lack of empirical Wortmannin in vivo data containing the yields, ΦH were determined in an indirect empirical manner for various environmental conditions in the sea in numbers sufficient for the statistical generalizations to be meaningful. The model was thus developed in the indirect way described in section 2, with

the aid of two models of this type that I had derived earlier, either independently or in cooperation with others, namely, the model of natural fluorescence SICF and the model of photosynthesis in the sea. But deriving such a model of the quantum yield of the heat production by phytoplankton pigments from directly determined empirical values of ΦH requires such data to be gathered in amounts sufficient for making the requisite statistical generalizations. Further research in this direction is needed and is being planned. Described set of these three models used simultaneously can be used to balance the quantum yields of the deactivation of the excited states of molecules of all pigments or just chlorophyll a in the sea. This will be applied in the next

work, the aim of which will be to characterize quantitatively the quantum yields Resminostat of the chlorophyll a fluorescence and its quenchings in different marine system of the World Ocean (see Ostrowska et al. (2012) – in this volume). “
“One of the most important processes sustaining life on Earth is the photosynthesis of organic matter and the liberation of oxygen in plant cells. The phytoplankton of seas and oceans make up the vast majority of these cells. The photosynthetic primary production of phytoplankton is the first link in the trophic chain of marine organisms, which supplies marine ecosystems with energy and controls the inflow of this energy (Steemann Nielsen, 1975, Lieth and Whittaker, 1975, Kowda, 1976, Falkowski, 1980, Kirk, 1994 and Woźniak et al., 2003). Marine phytoplankton is also one of the main regulators of the balance between oxygen and carbon dioxide in nature (e.g. Glantz, 1988, Kellogg, 1988, Trenberth, 1992, Kożuchowski and Przybylak, 1995, Michael et al., 2006 and Armbrust, 2009). It therefore influences the greenhouse effect in the Earth’s atmosphere and hence the planet’s climate.

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