These results are given in Annex 3 in Table A3.5 and Table A3.6, and also on the plots in Figure 7. Table A3.5 gives the ranges and average quantum yields of the fluorescence (<Φflze>,<Φfl>ze,ze), heat production (<ΦHze>,<ΦH>ze,ze), and photosynthesis (<Φphze>,<Φph>ze,ze) expressed as percentages of the number of quanta consumed by phytoplankton in the euphotic zone. Each of these average yields in waters of different trophic types, given in Table A3.5, is the arithmetic mean of the set of six average values weighted by the yield

within the euphotic zone (calculated using (17) and (18) respectively), i.e. the values for two seasons in three climatic zones. C59 wnt The maximum and minimum values given in this table are respectively the largest Nivolumab and smallest of this set of six values. Analogously, the typical ranges and average energy efficiencies of fluorescence (,ze,ze),

heat production (,ze,ze) and photosynthesis (,ze,), expressed as percentages of the energy consumed by phytoplankton in the euphotic zone are given in Annex 3, Table A3.6. The plots in Figure 7 illustrate the complete budget of the number of absorbed quanta or the amount of excitation energy in phytoplankton pigment molecules expended on the three deactivation processes under scrutiny here. They represent

the ranges of their values come across in sea waters of different trophic types and normalized to 100%, and refer to all four types of yield/efficiency, i.e. Φ, q  , R  , r   defined by (1), (2), (3), (4), (5), (6), (7), (8), (9), (10), (11) and (12) and averaged over the euphotic zone according to (17), (18), (19) and (20), as described click here above (see plots 7a, b, c, d). These data show that heat production is much or very much greater than fluorescence or photosynthesis in waters of all trophic types and in every possible combination of environmental factors. For example, the average portion of heat production in the overall excitation energy budget, illustrated in Figure 7c, is always in excess of 90% and decreases only slightly with increasing Ca  (0). We demonstrate this by analysing the energy efficiencies ,ze,ze and ze, averaged as above, that is, with reference to the total amount of energy absorbed by phytoplankton pigments in the water column throughout the euphotic zone. The portions of fluorescence and photosynthesis in this budget are much lower. The average portion of fluorescence is ca 10% in oligotrophic waters of type O1 and falls with increasing trophic index, reaching values approaching zero (< 1%) in supereutrophic waters.