Abstract
The annual loads of C,N,P, silicate, total suspended sediment (mass) and their yields (mass area−1) were estimated for six watersheds of the Mississippi River Basin (MRB) using water quality and water discharge records for 1973 to 1994. The highest load of suspended sediments is from the Missouri watershed (58 mt km2 yr−1), which is also the largest among the six major sub-basins. The Ohio watershed delivers the largest load of water (38%). The Upper Mississippi has the largest total nitrogen load (32%) and yield (1120 kg TN km2 yr−1). The loading of organic carbon, total phosphorus and silicate from the Upper Mississippi and Ohio watersheds are similar and relatively high (range 2.1–2.5, 0.068–0.076, and 0.8–1.1 mt km2 yr−1, respectively). The yields of suspended sediments, total phosphorus, total nitrogen, and silicate from the Lower Mississippi watershed are disproportionately the highest for its area, which is the smallest of all the watersheds and has the weakest monitoring network. The loading from the Red and Arkansas watersheds are of lesser importance than the others for most parameters investigated. The total nitrogen loading to coastal waters increased an additional 150% since the early 1900s, and is now dominated by loads from the Upper Mississippi watershed, rather than the previously dominant Ohio watershed. An analysis of trends for 1973–1994 suggests variability among years, rather than uni-directional change for most variables among 11 key stations. Explanatory relationships were established or confirmed to describe TN and TP loadings in terms of the now largely human-created landscape arising mostly over the last 150 years.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alexander, R. B., A. S. Ludtke, K. K. Fitzgerald & T. L. Schertz, 1996. Data from selected U.S. Geological Survey national stream water-quality monitoring networks (WQN) on CD-ROM. U.S. Geological Survey Open-File Report 96-337, 79 pp.
Alexander, R. B., R. A. Smith & G. E. Schwarz, 2000. Effect of stream channel size on the delivery of nitrogen to the Gulf of Mexico. Nature 403: 758–761.
Arbuckle, K. E. & J. A. Downing, 2001. The influence of watershed land use on lake N:P in a predominantly agricultural landscape. Limnology and Oceanography 46: 970–975.
Caraco, N. F. & J. J. Cole, 1999. Human impact on nitrate export: An analysis using major world rivers. Ambio 28: 167–170.
Clarke, F.W., 1924. The composition of the river and lake waters of the United States. United States Geological Survey Professional Paper 135.
Cohn, T. A., D.L. Caulder, E. J. Gilroy, L. D. Zynjuk & R. M. Summers 1992. The validity of a simple statistical model for estimating fluvial constituent loads: an empirical study involving nutrient loads entering Chesapeake Bay. Water Resources Research 28: 2352–2363.
Curtis, W. F., J. K. Culbertson & E. B. Chase, 1973. Fluvialsediment discharge to the oceans from the conterminous United States. United States Geological Survey Circular 670.
Dole, R. B. & H. Stabler, 1909. Denudation. Pages 78-93 in Papers on the conservation of water resources. United States Geological Survey Water-Supply Paper 234, Washington DC.
Fisk, H. N., 1952. Geological investigation of the Atchafalaya basin and the problem of Mississippi River diversion. Vol. 1. Vicksburg (MS): United States Army Corps of Engineers, Waterways Experiment Station.
hypox.html#Topic3.
Howarth, R. W., G. Billen, D. Swaney A. Townsend, N. Jaworski, K. Lajtha, J. A. Downing, R. Elmgren, N. Caraco, T. Jordan, F. Berendse, J. Freney, v. Kudeyarov, P. Murdoch & Z. Zhao-Liang, 1996. Regional nitrogen budgets and riverine N & P fluxes for the drainages to the North Atlantic Ocean: Natural and human influences. Biogeochemistry 35: 75–139.
Jones, J. R., B. P. Borofka & R. W. Bachmann, 1976. Factors affecting nutrient loads in some Iowa streams. Water Research 10: 117–122.
Jordan, T. E. & D. E. Weller, 1996. Human contributions to terrestrial nitrogen flux. BioScience 46: 655–664.
Jordan, T. E, D. L. Correll & D. E. Weller, 1997. Relating nutrient discharges from watersheds to land use and streamflow variability. Water Resources Research. 33: 2579–2590.
Judson, S. & D. F. Ritter, 1964. Rates of denudation in the United States. Journal Geophysical Research 69: 3395–3401.
Keown, M. P., E. A. Dardeau Jr. & E. M. Causey, 1986. Historic trends in the sediment flow regime of the Mississippi River. Water Resources Research 22: 1555–1564.
Lurry, D. L. & D. D. Dunn, 1997. Trends in nutrient concentration and load for streams in the Mississippi River Basin, 1974-94. United States Geological Survey, Water-Resources Investigations Rept 97-4223.
Malcolm R. L. & W. H. Durum, 1976. Organic carbon and nitrogen concentrations and annual organic carbon load of six selected rivers of the United States. United States Geological Survey Water-Supply Paper 1817-F.
McIssac, G. F., M. B. David, G. Z. Gertner & D. A. Goolsby, 2002. Relating net nitrogen input in the Mississippi River basin to nitrate flux in the lower Mississippi River: A comparison of approaches. Journal of Environmental Quality 31: 1610–1622.
McIssac, G. F., M. B. David, G. Z. Gertner & D. A. Goolsby, 2001. Eutrophication-Nitrate flux in the Mississippi river. Nature 414: 166–167.
Meade, R. H., T. R. Yuzyk, & T. J. Day, 1990. Movement and storage of sediment in rivers of the United States and Canada. In: Wolman, M. G. & H. C. Riggs (eds), Surface Water Hydrology. Geological Society of America, The Geology of North America Volume O-1. Boulder, CO: 255–280.
Milliman, J. D. & R. H. Meade, 1983, World-wide delivery of river sediment to the oceans. Journal Geology 91: 1–21.
Peierls, B., N. Caraco, M. Pace & J. Cole, 1991. Human influence on river nitrogen. Nature 350: 386–387.
Perkins, B. D., K. Lohman, E. Van Nieuwenhuyse & J. R. Jones, 1998. An examination of land cover and stream water quality among physiographic provinces of Missouri, U.S.A. Verh. International Verin. fur Limnologie 26: 940–947.
Rabalais, N. N., R. E. Turner & D. Scavia, 2002. Beyond science into policy: Gulf of Mexico hypoxia and the Mississippi River. BioScience 52: 129–142.
Reynolds, A. R., 1902. Report of Streams Examination. Trustees of the Sanitary District of Chicago, Ill. Blakely Printing Co., Chicago (ILL).
Smart, M. M. J. R. Jones & J. L. Sebaugh, 1985. Streamwatershed relations in the Missouri Ozark Plateau Province. Journal Environmental Quality 14: 77–82.
Smith, R. A., R. B. Alexander & K. J. Lanfear, 1996. Stream water quality in the conterminous United States-Status and trends of selected indicators during the 1980s. USGS Water Supply Paper 2400. Washington, D.C.
Turner, R. E. & N. N. Rabalais, 1991. Changes in the Mississippi River this century: Implications for coastal food webs. BioScience 41: 140–147.
Turner, R. E., D. Stanley, D. Brock, J. Pennock & N. N. Rabalais, 2000. A comparison of independent N-loading estimates for U.S. estuaries. In: Valigura, R. W., R. B. Alexander, M. S. Castro, T. P. Meyers, H. W. Paerl, P. E. Stacey, & R. E. Turner (eds). Nitrogen Loading in CoastalWater Bodies: An Atmospheric Perspective. Coastal and Estuarine Studies, Vol. No. 57. American Geophysical Union, Washington, D.C.; 107–118.
Turner, R. E. & N. N. Rabalais 2003. Linking landscape and water quality in the Mississippi River Basin. BioScience 53: 563–572.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Turner, R.E., Rabalais, N.N. Suspended Sediment, C, N, P, and Si Yields from the Mississippi River Basin. Hydrobiologia 511, 79–89 (2004). https://doi.org/10.1023/B:HYDR.0000014031.12067.1a
Issue Date:
DOI: https://doi.org/10.1023/B:HYDR.0000014031.12067.1a