Spatio-temporal decay 'hot spots' of stranded wrack in a Baltic sandy coastal system. Part I. Comparative study of the pattern : 1 type of wrack vs 3 beach sites

• Autorzy: Jędrzejczak M. F.
• Języki publikacji: EN

Abstrakty

EN

The significance of distance along the beach-dune transect and different moisture conditions as regards the decay of Zostera marina leaf litter was investigated in simple field experiments in three temperate, medium- to fine-quartz-sediment, sandy beaches of the Gulf of Gdansk in Poland. 1800 replicate litterbags of freshly stranded Zostera marina leaves were placed in beach sediments at different strata and levels on each of the beaches. The litterbags were sampled after 5, 10, 50, 100 and 150 days in the field and the remaining material was then dried and weighed. Under similar conditions of sediment composition, salinity and wave inundation, ANOVA tests revealed significant differences in breakdown through time and site. Thus there were some differences in the decay process between the low and high beach. In the former, degradation proceeded rapidly in the initial stages and then stabilised, while in the latter it remained linear throughout the study period. Matter loss in each stratum was also seasonally dependent. This may, however, be more closely linked to successional changes in the chemistry and/or microflora of the beach wrack than to its physical breakdown. Differences between organic matter degradation in the high and low beaches may be explained by differences in the moisture regime and nutrient status, and not by differences in the decay processes themselves. Therefore, two decay centres were found in the beach-dune system: the low beach together with the strandline (wrack consumption 12-21% day-1 in the warm season, and 4-10% day-1 in the cold season) and the dune (active consumption 2-6% day-1 in the warm season only).

Słowa kluczowe

EN

sandy beach system; decomposition; Zostera marina; hot spots; spatio-temporal variations

• Wydawca: Polish Academy of Sciences, Institute of Oceanology ; Elsevier
• Czasopismo: Oceanologia
• Rocznik: 2002
• Tom: No. 44 (4)
• Strony: 491--512
• Opis fizyczny: Bibliogr. 46 poz., rys., tab., wykr.

Twórcy

autor

Jędrzejczak M. F.

• Department of Environmental Chemistry and Ecotoxicology, Faculty of Chemistry, University of Gdańsk, Jana III Sobieskiego 18/19, PL-80-952 Gdańsk, Poland
• Dipartimento di Biologia Animale e Genetica ‘Leo Pardi’, Università degli Studi di Firenze, Via Romana 17, I-50125 Firenze, Italia

Bibliografia

• [1] Brazeiro A., Defeo O., 1996, Macroinfauna zonation in microtidal sandy beaches:is it possible to identify patterns in such variable environments?, Estuar. Coast. Shelf Sci., 42, 523-536.
• [2] Brown A. C., McLachlan A., 1990, Ecology of sandy shores, Elsevier, Amsterdam, 328 pp.
• [3] Dahl E., 1952, Some aspects of the ecology and zonation of the fauna on sandy beaches, Oikos, 4, 1-27.
• [4] Defeo O., Brazeiro A., de Alava A., Riestra G., 1997, Is sandy beach macrofauna only physically controlled? Role of substrate and competition in isopods, Estuar. Coast. Shelf Sci., 45, 453-462.
• [5] Defeo O., Jaramillo E., Lyonnet A., 1992, Community structure and intertidal zonation of the macroinfauna on the Atlantic coast of Uruguay, J. Coast. Res., 8, 830-839.
• [6] Druet Cz., Massel S., Zeidler R., 1972, Statistical characteristics of wind-induced wave action in the coastal zone of the Gulf of Gdańsk and in the open Baltic, Rozpr. Hydrot., 30, 49-84, (in Polish).
• [7] Dye A. H., 1980, Tidal fluctuations in biological oxygen demand in exposed sandy beaches, Estuar. Coast. Shelf. Sci., 11, 1-8.
• [8] Dye A. H., 1981, A study of benthic oxygen consumption on exposed sandy beaches, Estuar. Coast. Shelf Sci., 13, 671-680.
• [9] Eagle G. A., 1983, The chemistry of sandy beach ecosystems – a review, [in:] Sandy beaches as ecosystems, A. McLachlan & T. Erasmus (eds.), W. Junk, The Hague, 203-224.
• [10] Fenchel T. M., Riedl R. J., 1970, The sulfide system:a new biotic community underneath the oxidized layer of marine sand bottoms, Mar. Biol., 7, 255-268.
• [11] Folk R. L., Ward W. C., 1957, Brazos River Bar:a study in the significance of grain size parameters, J. Sedim. Petrol., 27, 3-26.
• [12] Fowler J., Cohen L., Jarvis Ph., 1998, Practical statistics for field biology, Second Edition, John Wiley & Sons, Chichester, 260 pp.
• [13] Golden Software Inc., 1996, SURFER (Win32) Version 6.02.22 Surface Mapping System (Computer program manual), Golden, CO: Golden Software, Inc., 809 14th Street, Golden, CO, 80401-1866, sales: 8000-972-1021, tech support: 303-279-1021.
• [14] Hackney C. T., 1987, Factors affecting accumulation or loss of macroorganic matter in salt marsh sediments, Ecology, 68, 1109-1113.
• [15] Inglis G., 1989, The colonisation and degradation of stranded Macrocystis pyrifera (L.) C. Ag. by the macrofauna of a New Zealand sandy beach, J. Exp. Mar. Biol. Ecol., 125, 203-217.
• [16] Jaramillo E., McLachlan A., Coetzee P., 1993, Intertidal zonation patterns of macroinfauna over a range of exposed sandy beaches in south-central Chile, Mar. Ecol. Prog. Ser., 101, 105-118.
• [17] Jenny H., Gessel S. P., Bringham F. T., 1949, Comparative study of decomposition rates of organic matter in temperate and tropical regions, Soil Sci., 68, 419-432.
• [18] Jędrzejczak M. F., 1999, The degradation of stranded carrion on a Baltic Sea sandy beach, Oceanol. Stud., 28 (3)-(4), 109-141.
• [19] Jędrzejczak M. F., 2002a, Stranded Zostera marina L. vs wrack fauna community interactions on a Baltic sandy beach (Hel, Poland):a short-term pilot study. Part I. Driftline effects of fragmented detritivory, leaching and decay rates, Oceanologia, 44 (2), 273-286.
• [20] Jędrzejczak M. F., 2002b, Stranded Zostera marina L. vs wrack fauna community interactions on a Baltic sandy beach (Hel, Poland):a short-term pilot study. Part II. Driftline effects of succession changes and colonisation by beach fauna, Oceanologia, 44 (3), 367-387.
• [21] Koop K., Lucas M. I., 1983, Carbon flow and nutrient regeneration from the decomposition of macrophyte debris in a sandy beach microcosm, [in:] Sandy beaches as ecosystems, A. McLachlan & T. Erasmus (eds.), W. Junk, The Hague, 249-262.
• [22] Koop K., Newell R. C., Lucas M. I., 1982, Microbial regeneration of nutrients from the decomposition of macrophyte debris on the shore, Mar. Ecol. Prog. Ser., 9, 91-96.
• [23] Massel S. R., 2001, Circulation of groundwater due to wave set-up on a permeable beach, Oceanologia, 43 (3), 279-290.
• [24] McLachlan A., 1978, A quantitative analysis of the meiofauna and the chemistry of the redox potential discontinuity zone in a sheltered sandy beach, Estuar. Coast. Shelf Sci., 7, 275-290.
• [25] McLachlan A., 1979, Volumes of sea water filtered through eastern Cape sandy beaches, S. Afr. J. Sci., 75, 75-79.
• [26] McLachlan A., 1980, The definition of sandy beaches in relation to exposure: a simple rating system, S. Afr. J. Sci., 76, 137-138.
• [27] McLachlan A., 1982, A model for the estimation of water filtration and nutrient regeneration by exposed sandy beaches, Mar. Environ. Res., 6, 37-47.
• [28] McLachlan A., 1983, Sandy beach ecology – a review, [in:] Sandy beaches as ecosystems, A. McLachlan & T. Erasmus (eds.), W. Junk, The Hague, 321-380.
• [29] McLachlan A., 1990, Dissipative beaches and macrofauna communities on exposed intertidal sands, J. Coast. Res., 6, 57-71.
• [30] McLachlan A., Jaramillo E., Defeo O., Dugan J., de Ruyck A., Coetzee P., 1995, Adaptations of bivalves to different beach types, J. Exp. Mar. Biol. Ecol., 187, 147-160.
• [31] McLachlan A., Jaramillo E., Donn T. E., Wessels F., 1993, Sandy beach macrofauna communities and their control by the physical environment:a geographical comparison, J. Coast. Res., 15, 27-38, (special issue).
• [32] Riedl R. J., 1971, How much seawater passes through sandy beaches?, Int. Rev. gs. Hydrobiol., 56 (6), 923-946.
• [33] Riedl R. J., McMahan E. A., 1974, High energy beaches, [in:] Coastal ecological systems of the United States Sandy beaches as ecosystems. Vol. 1, H. T. Odum, B. J. Copeland & E. A. McMahan (eds.), The Conservation Foundation, Washington, 180-251.
• [34] Salvat B., 1964, Les conditions hydrodynamiques interstitielles de sédiments meubles intertidaux et la répartition verticale de la faune endogée, C. R. Acad. Sci. Paris, 259, 1576-1579.
• [35] Scapini F., 2002, Baseline research for the integrated sustainable management of Mediterranean sensitive coastal ecosystems. A manual for coastal managers, scientists and all those studying coastal processes and management in the Mediterranean, Istituto Agronomico per l’Oltremare, Firenze, 223 pp.
• [36] Short A. D., Wright L. D., 1983, Physical variability of sandy beaches, [in:] Sandy beaches as ecosystems, A. McLachlan & T. Erasmus (eds.), W. Junk, The Hague, 133-144.
• [37] StatSoft Inc., 1995, STATISTICA for Windows (Computer program manual), Tulsa, OK: StatSoft, Inc., 2325 East 13th Street, Tulsa, OK, 74104, (918) 583-4149, fax: (918) 583-4376, e-mail: info@statsoft.com, WEB: http://www.statsoft.com.
• [38] Swift J. M., Heal O. W., Anderson J. M., 1979, Decomposition in terrestrial ecosystems. Studies in ecology Vol. 5, Blackwell Sci. Publ., Oxford, 372 pp.
• [39] Underwood A. J., 1981, Techniques of analysis of variance in experimental marine biology and ecology, Oceanogr. Mar. Biol. Ann. Rev., 19, 513-605.
• [40] Urban-Malinga B., Opaliński K. W., 1999, Total, biotic and abiotic oxygen consumption in a Baltic sandy beach:horizontal zonation, Oceanol. Stud., 28 (3)-(4), 85-96.
• [41] Urban-Malinga B., Opaliński K. W., 2001, Interstitial community respiration in a Baltic sandy beach: horizontal zonation, Oceanologia, 43 (4), 455-468.
• [42] Veloso V. G., Cardoso R. S., 2001, Effect of morphodynamics on the spatial and temporal variation of macrofauna on three sandy beaches, Rio de Janeiro State, Brazil, J. Mar. Biol. Ass. U. K., 81, 369-375.
• [43] Wachendorf C., Irmler U., Blume H. P., 1997, Relationships between litter fauna and chemical changes of litter during decomposition under different moisture conditions, [in:] Driven by nature. Plant litter quality and decomposition, G. Cadish & K. E. Giller (eds.), CAB Int., London, 135-144.
• [44] Węsławski J. M., Urban-Malinga B., Kotwicki L., Opaliński K. W., Szymelfenig M., Dutkowski M., 2000, Sandy coastlines – are there conflicts between recreation and natural values?, Oceanol. Stud., 29 (2), 5-18.
• [45] Wieder R. K., Lang G. E., 1982, A critique of the analytical methods used in examining decomposition data obtained from litter bags, Ecology, 63, 1636-1642.
• [46] Zar J. H., 1999, Biostatistical analysis. (4th edn.), Prentice-Hall Int., Inc. Englewood Cliffs, New Jersey, 663 pp. + 212 app.