Abstract
We describe statistical relationships between chemical aspects of surficial sediments from 34 Florida lakes, and trophic state of the overlying waters. Trophic state is expressed by Carlson’s TSI-Chl a. The objectives of the study are two-fold: 1) to understand processes that govern the transfer of material across the mudwater interface, and 2) to develop transfer functions for inferring historical TSI measures in chemically analyzed, 210Pb-dated cores. Simple regression of organic matter content or nutrient (C, N, P) concentration in surface sediments vs. TSI yields nonsignificant or weak positive correlations. However, using a novel application of 210Pb assay, net accumulation rates of the materials are estimated and show a better correlation with trophic state. Cation (Ca, Mg, Fe, K) and sulfur concentrations in surface muds are poorly related to corresponding TSI’s. Net accumulation rates of these elements (Ca, Mg, Fe, K, S) are positively correlated (P < 0.01) with TSI-Chl a. Chemical data from the Florida surficial sediment survey suggest that inferred levels of past trophic state should be based on net accumulation rates of chemical constituents rather than their simple sediment concentrations.
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References
American Public Health Association, 1975. Standard methods for the examination of water and wastewater, 14th ed.
Andersen, J. M., 1976. An ignition method for determination of total phosphorus in lake sediments. Wat. Res. 10: 329–331.
Baker, L. A., P. L. Brezonik & C. R. Kratzer, 1981. Nutrient loading — trophic state relationships in Florida lakes. Publication 56, Water Resources Research Center, Univ. of Florida, Gainesville.
Binford, M. W. & M. Brenner, 1986. Dilution of 210Pb by organic sedimentation in lakes of different trophic states and application to studies of sediment-water interactions. Limnol. Oceanogr. 31: 584–595.
Binford, M. W., E. S. Deevey & T. L. Crisman, 1983. Paleolimnology: an historical perspective on lacustrine ecosystems. Ann. Rev. Ecol. Syst. 14: 255–286.
Brenner, M. & M. W. Binford, in prep. Relationships between concentrations of sedimentary variables and trophic state in Florida lakes.
Brezonik, P. L., W. H. Morgan, E. E. Shannon & A. D. Putnam, 1969. Eutrophication factors in north central Florida lakes. Publication No.5, Water Resources Research Center, Univ. of Florida., Gainesville.
Canfield, D. E., Jr., 1981. Chemical and trophic state characteristics of Florida lakes in relation to regional geology. Final Report to Cooperative Fish and Wildlife Research Unit, Univ. of Florida, Gainesville, Contract No. 14-16-0009-79-064. 444 pp.
Canfield, D. E., Jr., 1983. Prediction of chlorophyll a concentrations in Florida lakes: the importance of phosphorus and nitrogen. Wat. Res. Bull. 19: 255–262.
Carlson, R. E., 1977. A trophic state index for lakes. Limnol. Oceanogr. 22: 361–369.
Dean, W. E., Jr., 1974. Determination of carbonate and organic matter in calcareous sediments and sedimentary rocks by loss on ignition: Comparison with other methods. J. Sed. Pet. 44: 242–248.
Dean, W. E., Jr. & E. Gorham, 1976. Major chemical and mineral components of profundal surface sediments in Minnesota lakes. Limnol. Oceanogr. 21: 259–284.
Deevey, E. S., Jr., 1984. Stress, strain, and stability of lacustrine ecosystems. p. 203–229. In E. Y. Haworth & J. W. G. Lund (eds.), Lake sediments and environmental history. University of Minnesota Press, Minneapolis, 411 pp.
Eakins, J. D. & R. T. Morrison, 1978. A new procedure for the determination of Lead-210 in lake and marine sediments. Int. J. appl. Radiat. Isotopes. 29: 531–536.
Flannery, M. S., R. D. Snodgrass & T. J. Whitmore, 1982. Deepwater sediments and trophic conditions in Florida lakes. Hydrobiologia 92: 597–602.
Gorham, E., 1960. Chlorophyll derivatives in surface muds from the English lakes. Limnol. Oceanogr. 5: 29–33.
Gorham, E., W. G. Lund, J. E. Sanger & W. E. Dean, Jr., 1974. Some relationships between algal standing crop, water chemistry, and sediment chemistry in the English Lakes. Limnol. Oceanogr. 19: 601–617.
Guilizzoni, P., G. Bonomi, G. Galanti & D. Ruggiu, 1983. Relationship between sedimentary pigments and primary production: evidence from core analyses of twelve Italian lakes. Hydrobiologia 103: 103–106.
Huber, W. c., P. L. Brezonik, J. P. Heaney, R. E. Dickinson, S. D. Preston, D. S. Dwornik & M. A. DeMaio, 1982. A classification of Florida Lakes. Final Report ENV-05-82-1 to the Florida Department of Environmental Regulation, Tallahassee, Florida.
Morris, A., 1983. The Florida handbook 1983–1984, 19th ed. The Peninsular Publishing Company, Tallahassee, Fl. 693 pp.
Prepas, E. E. & J. Vickery, 1984. Contribution of particulate phosphorus (> 250 μm) to the total phosphorus pool in lake water. Can. J. Fish. aquat. Sci. 41: 351–363.
Rybak, J.I., 1969. Bottom sediments of the lakes of various trophic type. Ekol. Pol. A: 611–662.
Shannon, E. E. & P. L. Brezonik, 1972a. Relationships between lake trophic state and nitrogen and phosphorus loading rates. Envir. Sci. Tech. 6: 719–725.
Shannon, E. E. & P. L. Brezonik, 1972b. Eutrophication analysis: a multivariate appraoch. Journal of the Sanitary Engineering Division, Proc. am. Soc. civ. Engineers 98, SA1: 37–57.
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© 1987 Dr W. Junk Publishers, Dordrecht
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Brenner, M., Binford, M.W. (1987). Material transfer from water to sediment in Florida lakes. In: Löffler, H. (eds) Paleolimnology IV. Developments in Hydrobiology, vol 37. Springer, Dordrecht. https://doi.org/10.1007/978-94-009-4047-5_9
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DOI: https://doi.org/10.1007/978-94-009-4047-5_9
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