Abstract
Sediment from agricultural, logging, and mining activities impairs more miles of rivers and streams in the United States than any other type of pollutant, including bacteria, nutrients, oxygen-depleting substances, and metals. However, specific impacts of sediment to streams have not been well studied or understood. To study the effect of inorganic sediment on plant and animal communities in stream ecosystems, we added clay to outdoor experimental streams 520 m long and 3.5 m wide at the Monticello Ecological Research Station (MERS). The streams take water from the Mississippi River and are designed to represent higher order streams in the upper midwestern United States. The sediment loading rates were 300, 200, 100, and 50 mg l−1. Our first dosing period (mid-August to November 1994) began at the start of a fall bloom in autotroph productivity, and the second (May to August 1995) began before the summer communities were established. During both treatment seasons, the addition of clay significantly increased turbidity and sedimentation, and decreased light penetration in treated streams corresponding roughly to 30–35, 25–30, 15–20, and 5–10 NTU, respectively. In general, the macrophyte and periphyton communities responded quickly after only a few weeks exposure to the sediment additions. Whole-stream respiration was significantly lower in treated streams, decreasing as the amount of sediment added increased. Periphyton biomass (chl a) on tiles and percent cover of macrophytes was significantly lower in treatment streams than in controls. In contrast to expectations and previous findings in two sets of field streams, total whole-stream productivity in the MERS streams was not significantly lower in streams receiving sediment loads than in control streams because the overall photosynthetic efficiency by the plant community compensated for the loss in irradiance.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Cline, L. D., R. A. Short & J.V. Ward, 1982. The influence of highway construction on the macroinvettebrates and epilithic algae of a high mountain stream. Hydrobiologia. 96: 149–159.
Cole, G.A., 1983, Textbook of Limnology, 3rd edn. Waveland Press, Inc. Prospect Heights, Illinois.
Cordone, A. J. & D. W. Kelley, 1961. The influences of inorganic sediment on the aquatic life of streams. CaiW Fish Game 47: 189–228.
Davies-Colley, R. J., C.W. Hickey, J. M. Quinn & P. A. Ryan, 1992. Effects of clay discharges on streams: 1. Optical properties and epilithon. Hydrobiologia 248: 215–234.
Detenbeck, N. E., P.W. DeVore, G. H. Niemi & A. Lima, 1992. Recovery of temperate-stream fish communities from disturbance: a review of case studies and synthesis of theory. Environ. Manage. 16: 33–53.
Edwards, D., 1969. Some effects of siltation upaon aquatic macrophyte vegetation in rivers. Hydrobiologia. 34: 29–37.
Falkowski, P. G., 1981. Light-shade adaption and assimilation numbers. I Plankton Res. 3: 203–216.
Gardner, M. B., 1981. Effects of turbidity on feeding rates and selectivity of bluegills. Trans. am. Fish. Soc. 110: 446–450.
Gons, H. J. & M. Rijkeboer, 1992. The ‘true’ growth efficiency of phytoplankton as influenced by light attenuation and insolation: implications of the photosynthesis–irradiance relationship. Hydrobiologia 238: 169–176.
Grobbelaar, J. U., 1984. Phytoplankton productivity in a shallow turbid impoundment, Wuras Dam. Verh. int. Ver. Limnol. 2: 1594–1601.
Grobbelaar, J. U., 1992. Nutrients versus physical factors in determining the primary productivity of waters with high inorganic turbidity. Hydrobiologia. 238: 177–182.
Gulliver, J. S. & H. G. Stefan, 1984. Stream productivity analysis with DORM-II: Parameter estimation and sensitivity. Wat. Res. 18: 1577–1588.
Hahn, M. G., J. S. Gulliver & H. G. Stefan, 1978. Physical characteristics of the experimental field streams at the US EPA Ecological Research Station in Monticello, Minnesota. University of Minnesota, St. Anthony Falls Hydraulic Laboratory External Memo 156.
Hibbs, D. E., K. L. Parkhill & J. S. Gulliver, 1998. Sulfur hexa-fluoride gas tracer studies in streams. J. Environ. Eng. 124(8): 752–760.
Hill, W. R., M. G. Ryon & E. M. Schilling, 1995. Light limitation in a stream ecosystem: Responses by primary producers and consumers. Ecology 76(4): 1297–1309.
Hutchinson, G. E., 1957. A Treatise on Limnology. Volume 1, John Wiley, New York, NY: 366–425.
Judy, R. D., P. N. Seeley, T. M. Murray, S. C. Svirsky, M. R. Whitwotth & L. S. Ischinger, 1984. 1982 National Fisheries Survey: Volume I, technical report: Initial findings. FWS/OBS-84/06. Biol. Serv. Prog., U.S. Fish Wildl. Serv., Washington DC.
Kirk, J. T. O., 1983. Light and Photosynthesis in Aquatic Ecosystems. Cambridge University. Press, New York, NY.
Lloyd, D. S., J. P. Koenings & J. D. La Perriere, 1987. Effects of turbidity in fresh waters of Alaska. N. am. I Fish. Man. 7: 18–33
McCabe, G. D. & W. J. O'Brien, 1983. The effects of suspended silt on the feeding and reproduction of Daphnia pulex. Am. Midland Naturalist 110: 324–337.
McIntyre, C. D., R. L. Garrison, H. K. Phinney & C. E. Warren, 1964. Primary production in laboratory streams. Limnol. Oceanogr. 9: 92–102.
Morel, A. & R. C. Smith, 1974. Relation between total quanta and total energy for aquatic photosynthesis. Limnol. Oceanogr. 19: 591–600.
Niemi, G. J., P. DeVore, N. Detenbeck, D. Taylor, A. Lima, J. Pastor, J. D. Yount & R. J. Naiman, 1990. Overview of case studies on recovery of aquatic systems from disturbance. Environ. Manage. 15: 571–587.
Odum, H. T., 1956. Primary production of flowing waters. Limnol. Oceanogr. 1: 102–117.
Osmond, C. B. & S. C. Grace, 1995. Perspectives on photoinhibition and photorespiration in the field: Quintessential inefficiencies of the light and dark reactions of photosynthesis. J. of exp. Bot. 46: 1351–1362.
Parkhill, K. L. & J. S. Gulliver, 1998. Whole stream productivity in experimental streams. Hydrobiologia, 398: 7–19.
Parkhill, K. L. & J. Gulliver, 1999. Modeling the effect of light on whole-stream respiration. Ecol. Model. 117: 333–342.
Platt, T., C. L. Gallegos & W. G. Harrison, 1980. Photoinhibition of photosynthesis in natural assemblages on marine phytoplankton. J. mar. Res. 38: 687–701.
Richards, C. & K. Bacon, 1994. Influences of fine sediment on macroinvertebrate colonization of surface and hyporheic stream substrates. Great Basin Naturalist 54: 106–113.
Ryder, G. L., 1989. Experimental studies on the effects of fine sediments on lotic invertebrates. Unpublished Ph.D. thesis, University of Otago, Dunedin, New Zealand, 216 pp.
Sheldon, S.P.& M. K. Taylor, 1982. Community photosynthesis and respiration in experimental streams. Hydrobiologia 87: 3–10.
Sorenson, D. L., M. tiMcCarthy, E. J. Middlebrooks & D. B. Porcella, 1977. Suspended and dissolved solids effects on freshwater biota: A review. U.S. Environmental Protection Agency, Report 600/3-77-042, Environmental Research Laboratory, Corvallis, OR: 64 pp.
Stefan H. G., J. S. Gulliver, M. G. Hahn & A. Y. Eu, 1980. Water temperature dynamics in experimental field streams: analysis and modeling. University of Minnesota, St. Anthony Falls Hydraulic Laboratory Project Report No. 193.
Stefan, H. G., J. J. Cardoni, F. R. Schiebe & C. M. Cooper, 1983. Model of light penetration in a turbid lake. Water Res. Res. 19: 109–120.
United States Environmental Protection Agency, Office of Water, 1995. National Water Quality Inventory: 1994 Report to Congress. Washington, DC. EPA 841-R-95-005.
Van Nieuwenhuyse, E. E. & J. D. LaPerriere. 1986. Effects of placer gold mining on primary production in subarctic streams of Alaska. Water Res. Bull. 22: 91–99.
Waters, T. F., 1995. Sediment in streams: Sources, biological effects and control. Am. Fish. Soc. Monogr. 7.
Wadworth, H. M., 1990. Handbook of Statistical Methods for Engineers and Scientists. McGraw Hill, Inc. New York, NY.
Zaneveld, J. R. V. & R. W. Spinrad, 1980. An arc tangent model of irradiance in the sea. J. geophys. Res. 85: 4919–4922.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Parkhill, K.L., Gulliver, J.S. Effect of inorganic sediment on whole-stream productivity. Hydrobiologia 472, 5–17 (2002). https://doi.org/10.1023/A:1016363228389
Issue Date:
DOI: https://doi.org/10.1023/A:1016363228389