Photosynthetic rate and light curves of phytoplankton in the southern Baltic

• Autorzy: Renk H. , Ochocki S.
• Języki publikacji: EN

Abstrakty

EN

The paper presents photosynthetic curves for the phytoplankton population at three stations located in the Polish Economic Zone of the Baltic Sea, i.e. in the Gdansk and Bornholm Deeps and in the southern part of the Gotland Deep. Studies were carried out in 1995-1998. Assimilation numbers varied from 1.59 to 6.81 mgC mgChl-1 h-1, the average value being 3.31 mgC mgChl-1 h-1. Irradiation of photosynthesis saturation ranged from 216 to 673 kJ m-2 h-1. The seasonal variations in assimilation number and its dependence on water temperature are described.

Słowa kluczowe

EN

Southern Baltic; photosynthetic rate; assimilation number; photosynthetic light curves

• Wydawca: Polish Academy of Sciences, Institute of Oceanology ; Elsevier
• Czasopismo: Oceanologia
• Rocznik: 1998
• Tom: No. 40 (4)
• Strony: 331--344
• Opis fizyczny: Bibliogr. 43 poz., tab., wykr.

Twórcy

autor

Renk H.

autor

Ochocki S.

• Sea Fisheries Institute, Kołłataja 1, 81-332 Gdynia, Poland,

Bibliografia

• 1. Aertebjerg Nielsen G., Bresta A. M., 1984, Guidelines for the measurement of phytoplankton primary production, Baltic Mar. Biol. Publ., 1, 1-23.
• 2. Bannister T. T., Laws E. A., 1980, Modelling phytoplankton carbon metabolism [in:] Primary productivity in the sea, P. G. Falkowski (ed.), Plenum Press, New York, 243-258.
• 3. Baretta V., Ebenhoh W., Raurdij P., 1995, The European Regional Seas Ecosystem Model, a complex marine ecosystem model, Neth. J. Sea Res., 33, 223-246.
• 4. BMEPC, 1988, Guidelines for the Baltic Monitoring Programme – the third stage, Baltic Mar. Environm. Protect. Comm., Helsinki, 1-161.
• 5. Dera J., 1995, Underwater irradiance as a factor affecting primary production, Diss. and monogr., Inst. Oceanol. PAS, Sopot, 7, 110 pp.
• 6. Dugdale R. C., 1967, Nutrient limitation in the sea: dynamics, identification and significance, Limnol. Oceanogr., 12, 685-695.
• 7. Eppley R. W., 1972, Temperature and phytoplankton growth in the sea, Fish. Bull., 70 (4), 1063-1085.
• 8. Eppley R. W., Coatsworth J. L., 1968, Nitrate and nitrite uptake by Ditylum brightwellii. Kinetics and mechanisms, J. Phycol., 4, 151-156.
• 9. Eppley R. W. J., Rogers E. M., McCarthy J. J., 1969, Half-saturation constants for uptake of nitrate and ammonium by marine phytoplankton, Limnol. Oceanogr., 14, 912-920.
• 10. Evans C. A., O’Reilly J. E., Thomas J. P., 1987, A handbook for the measurement of chlorophyll a and primary productivity, BIOMASS Sci. Ser., 8, 1-114.
• 11. Falkowski P., 1980, Light-shade adaptation in marine phytoplankton, [in:] Primary productivity in the sea, P. G. Falkowski (ed.), Plenum Press, New York, 99-119.
• 12. Geider R. J., 1993, Quantitative phytoplankton physiology: implications for primary production and phytoplankton growth, ICES Mar. Sci. Symp., Int. Council Explor. Sea, Copenhagen, 197, 52-62.
• 13. Grasshoff K., Ehrhardt M., Kremling K., 1983, Methods of seawater analysis, Verlag Chem., Weinheim, 63-97, 127-187.
• 14. Latała A., 1991, Photosynthesis and respiration of plants from the Gulf of Gdańsk, Acta Ichthyol. Piscat., 21 Suppl., 85-100.
• 15. Li W. K. W., 1980, Temperature adaptation in phytoplankton: Cellular and photosynthetic characteristics, [in:] Primary productivity in the sea, P. G. Falkowski (ed.), Plenum Press, New York, 259-279.
• 16. Lohrenz S. E., 1993, Estimation of primary production by the simulated in situ method, ICES Mar. Sci. Symp., Int. Council Explor. Sea, Copenhagen, 197, 159-171.
• 17. Marra J., 1980, Vertical mixing and primary production, [in:] Primary productivity in the sea, P. G. Falkowski (ed.), Plenum Press, New York, 121-137.
• 18. Nehring D., 1982, Langzeittrends des Phosphat- und Nitratgehalts in der Ostsee, Beitr. Meeresk., 47, 61-86.
• 19. Ochocki S., Chmielowski H., Nakonieczny J., Zalewski M., Seasonal and spatial distribution of in situ and potential production and chlorophyll a concentrations in the Pomeranian Bay 1996–97, (in preparation).
• 20. Parsons T. R., Takahashi M., 1973, Biological oceanographic processes, Pergamon Press, Oxford–New York, 185 pp.
• 21. Pastuszak M., Nagel K., Nautsch G., 1996, Variability in nutrient distribution in the Pomeranian Bay in September 1993, Oceanologia, 38 (2), 195-225.
• 22. Platt T., Denman K. I., Jassby A. D., 1977, Modelling the productivity of phytoplankton, [in:] The sea, E. D. Goldberg (ed.), John Wiley, New York, 6, 807-856.
• 23. Platt T., Gallegos C. L., 1980, Modelling primary production, [in:] Primary productivity in the sea, P. G. Falkowski (ed.), Plenum Press, New York-London, 339-362.
• 24. Redfield A. C., Ketchum B. H., Richards F. A., 1963, The influence of organisms on the composition of seawater, [in:] The sea, M. H. Hill (ed.), Wiley Interscience, New York, 2, 26-77.
• 25. Renk H., 1983, Light conditions, chlorophyll a distribution and primary production in the southern Baltic, Pol. Arch. Hydrobiol., 9, 311-329.
• 26. Renk H., 1989, Description of seasonal changes of hydrobiological parameters in the Gulf of Gdańsk using a trigonometric polynomial, Oceanologia, 27, 79-92.
• 27. Renk H., 1997, Primary production in the Gulf of Gdańsk, Wyd. Uniw. Gdańsk, Gdańsk, 84 pp., (in Polish).
• 28. Renk H., Torbicki H., Ochocki S., 1976, Distribution of chlorophyll in the sea in the vicinity of river estuaries, Stud. i Mater. Oceanol., 15, 187-202, (in Polish).
• 29. Renk H., Ochocki S., Pytel H., 1983, Short-term variations of primary production and chlorophyll in the Gdańsk Deep, Pol. Ecol. Stud., 9, 341-359.
• 30. Renk H., Ochocki S., Chmielowski H., Gromisz S., Nakonieczny J., Pastuszak M., Zalewski M., Photosynthetic light curves in the Pomeranian Bay, (in preparation).
• 31. Savchuk O., Wulff F., 1993, Biogeochemical transformations of nitrogen and phosphorus – a pelagic submodel for the Baltic, Sea Ecol. Contrib., 1, 1-50.
• 32. Semovski S. V., Woźniak B., 1995, Model of the annual phytoplankton cycle in the marine ecosystem – assimilation of monthly satellite chlorophyll data for the North Atlantic and Baltic, Oceanologia, 37 (1), 3-31.
• 33. Steele J. H., 1962, Environmental control of photosynthesis in the sea, Limnol. Oceanogr., 7, 137-149.
• 34. Steemann Nielsen E., 1952, The use of radi-carbon C–14 for measuring organic production in the sea, J. Cons. Int. Explor. Mer., 18, 117-140.
• 35. Steemann Nielsen E., 1965, On the determination of the activity in 14-C ampoules for measuring primary production, Linmol. Oceanogr., 10 R Suppl., 247-252.
• 36. Tilzer M. M., Hse C., Conrad I., 1993, Estimation of in situ primary production from parameters of the photosynthesis – light curve obtained in laboratory incubators, ICES Mar. Sci. Symp., Int. Council Explor. Sea, Copenhagen, 197, 181-195.
• 37. Trzosińska A., 1992, Nutrients, Stud. i Mater. Oceanol., 61, 107-130.
• 38. Trzosińska A., Pliński M., Rybiński J., 1989, Hydrochemical and biological characteristics of the Polish coastal zone, Stud. i Mater. Oceanol., 54, 5-70, (in Polish).
• 39. UNESCO, 1983, Chemical methods for use in marine environmental monitoring. Manual and guides, Intergovern. Oceanogr. Comm., 12, 1-53.
• 40. Vollenweider R. A., 1965, Calculation models of photosynthesis depth curves and some implications regarding day rate estimates in primary production measurements, Mem. Ist. Ital. Idrobiol., 18, 425-457.
• 41. Woźniak B., 1987, A semi-empirical, mathematical model of photosynthesis in marine phytoplankton and an optical method of estimating the global primary production in the sea, Bull. Pol. Acad. Sci., Earth Sci., 35, 71-89.
• 42. Woźniak B., Hapter R., Dera J., 1989, Light curves of marine plankton photosynthesis in the Baltic, Oceanologia, 27, 61-78.
• 43. Yentsch Ch. S., Lee R. W., 1966, A study of photosynthetic light reactions, and a new interpretation of sun and shade phytoplankton, J. Mar. Res. 24 (3), 319-337.