Historical changes in sediment and phosphorus loading to the upper Mississippi River: mass-balance reconstructions from the sediments of Lake Pepin

Long-term changes in sediment and phosphorus loading to the upper Mississippi River were quantified from an array of 25 sediment cores from Lake Pepin, a large natural impoundment downstream of the Minneapolis-St Paul metropolitan area. Cores were dated and stratigraphically correlated using 210Pb, 137Cs, 14C, magnetic susceptibility, pollen analysis, and loss-on-ignition. All cores show a dramatic increase in sediment accumulation beginning with European settlement in 1830. Accumulation rates are highest and show the greatest post-settlement increases in the upper end of the lake. Present-day sediment-phosphorus concentrations are roughly twice those of pre-settlement times, and the Fe/Al-bound fraction makes up a greater portion of the total. Diatom assemblages record a marked increase in nutrient availability over the last 200 years, changing from clear-water benthic forms and mesotrophic planktonic taxa in pre-settlement times to exclusively planktonic assemblages characteristic of highly eutrophic conditions today. Lake-water total-phosphorus concentrations, estimated by weighted averaging regression and calibration, increased from 50 to 200 μg l−1 during this period. Sediment loading to Lake Pepin from the Mississippi River has increased by an order of magnitude since 1830. Modern fluxes are about 900,000 metric tons annually, and are more than 80% detrital mineral matter. About 17% of the lake’s volume in 1830 has been replaced by sediment, and at current accumulation rates the remainder will be filled in another 340 years. Phosphorus accumulation in Lake Pepin sediments has increased 15-fold since 1830, rising from 60 to 900 metric tons annually. This rise represents a sevenfold increase in phosphorus loading from the Mississippi River coupled with more efficient retention of phosphorus inflows by bottom sediments. More efficient trapping of phosphorus in Lake Pepin over the last century resulted from higher rates of sediment burial. The most dramatic changes in nutrient and sediment inputs to Lake Pepin have occurred since 1940, although gradual increases began shortly following European settlement. Sediment accumulation rates rose sharply between 1940 and 1970 and then leveled off, while phosphorus inflows record their largest increases after 1970.

[1]  D. Engstrom,et al.  The chemistry of lake sediments in time and space , 1986, Hydrobiologia.

[2]  N. Anderson A Whole-Basin Diatom Accumulation Rate for a Small Eutrophic Lake in Northern Ireland and its Palaeoecological Implications , 1989 .

[3]  E. Haworth,et al.  Lake Sediments and Environmental History. , 1985 .

[4]  C. Sayer Problems with the application of diatom‐total phosphorus transfer functions: examples from a shallow English lake , 2001 .

[5]  C.J.F. ter Braak,et al.  A Theory of Gradient Analysis , 2004 .

[6]  J. Smol Paleophycology of a high arctic lake near Cape Herschel, Ellesmere Island , 1983 .

[7]  J. Bradbury,et al.  Paleolimnology of Two Lakes in the Klutlan Glacier Region, Yukon Territory, Canada , 1980, Quaternary Research.

[8]  S. Juggins,et al.  DIATOM ASSEMBLAGES AND IONIC CHARACTERIZATION OF LAKES OF THE NORTHERN GREAT-PLAINS, NORTH-AMERICA - A TOOL FOR RECONSTRUCTING PAST SALINITY AND CLIMATE FLUCTUATIONS , 1993 .

[9]  D. Engstrom,et al.  The Application of a Diatom-based Transfer Function to Evaluate Regional Water-Quality Trends in Minnessota Since 1970 , 2003 .

[10]  G. Brune Trap efficiency of reservoirs , 1953 .

[11]  R. E. Turner,et al.  SEDIMENTS TELL THE HISTORY OF EUTROPHICATION AND HYPOXIA IN THE NORTHERN GULF OF MEXICO , 2007 .

[12]  J. Dearing,et al.  Recent Sediment Flux and Erosional Processes in a Welsh Upland Lake-Catchment Based on Magnetic Susceptibility Measurements , 1981, Quaternary Research.

[13]  H. Tunney,et al.  Phosphorus Loss from Soil to Water , 1997 .

[14]  P. V. Van Metre,et al.  A land-use and water-quality history of White Rock Lake reservoir, Dallas, Texas, based on paleolimnological analyses , 1997 .

[15]  D. Engstrom,et al.  Twentieth century eutrophication of the St. Croix River (Minnesota–Wisconsin, USA) reconstructed from the sediments of its natural impoundment , 2009 .

[16]  P Jordan,et al.  Modeling diffuse phosphorus loads from land to freshwater using the sedimentary record. , 2001, Environmental science & technology.

[17]  Richard P. Hooper,et al.  Flux and Sources of Nutrients in the Mississippi-Atchafalaya River Basin , 1999 .

[18]  M. Binford,et al.  Calculation and uncertainty analysis of 210Pb dates for PIRLA project lake sediment cores , 1990 .

[19]  Russell H Plumb,et al.  Procedures for Handling and Chemical Analysis of Sediment and Water Samples , 1981 .

[20]  N. Anderson,et al.  Monitoring lake recovery from point‐source eutrophication: the use of diatom‐inferred epilimnetic total phosphorus and sediment chemistry , 1994 .

[21]  E. Stoermer,et al.  Variations in Melosira islandica valve morphology in Lake Ontario sediments related to eutrophication and silica depletion1 , 1985 .

[22]  W. Wiseman,et al.  Gulf of Mexico Hypoxia, A.K.A. “The Dead Zone” , 2002 .

[23]  Jerry C. Ritchie,et al.  RATES OF RECENT SEDIMENTATION IN LAKE PEPIN , 1980 .

[24]  John P. Smol,et al.  Paleolimnology: an important tool for effective ecosystem management , 1992 .

[25]  R. Morrison,et al.  A new procedure for the determination of lead-210 in lake and marine sediments , 1978 .

[26]  John P. Smol,et al.  A weighted—averaging regression and calibration model for inferring total phosphorus concentration from diatoms in British Columbia (Canada) lakes , 1992 .

[27]  E. Grimm Fire and Other Factors Controlling the Big Woods Vegetation of Minnesota in the Mid‐Nineteenth Century , 1984 .

[28]  K. Faegri,et al.  Textbook of Pollen Analysis , 1965 .

[29]  J. Smol Basin analysis, coring, and chronological techniques , 2001 .

[30]  S. Blomqvist Reliability of core sampling of soft bottom sediment-an in situ study , 1985 .

[31]  N. Rabalais,et al.  LSU Digital Commons LSU Digital Commons Coastal Eutrophication near the Mississippi River Delta Coastal Eutrophication near the Mississippi River Delta , 2022 .

[32]  D. Engstrom,et al.  Twentieth century water quality trends in Minnesota lakes compared with presettlement variability , 2004 .

[33]  R P Hooper,et al.  Nitrogen input to the Gulf of Mexico. , 2001, Journal of environmental quality.

[34]  H. E. Wright,et al.  Formation and early history of Lakes Pepin and St. Croix of the upper Mississippi River , 2009 .

[35]  B. J. Mason The Surface waters acidification programme , 1991 .

[36]  C. Fuller,et al.  Historical Trends in Organochlorine Compounds in River Basins Identified Using Sediment Cores from Reservoirs , 1997 .

[37]  S. Blomqvist,et al.  Quantitative sampling of soft-bottom sediments: problems and solutions , 1991 .

[38]  A diatom-phosphorus transfer function for shallow, eutrophic ponds in southeast England , 1994 .

[39]  E. Stoermer Phytoplankton Assemblages as Indicators of Water Quality in the Laurentian Great Lakes , 1978 .

[40]  Fish manipulation as a lake restoration tool in shallow, eutrophic, temperate lakes 2: threshold levels, long-term stability and conclusions , 1990 .

[41]  D. Conley,et al.  Sediment Record of Biogeochemical Responses to Anthropogenic Perturbations of Nutrient Cycles in Lake Ontario , 1988 .

[42]  Richard A. Smith,et al.  Natural background concentrations of nutrients in streams and rivers of the conterminous United States. , 2003, Environmental science & technology.

[43]  J. Smol The ratio of diatom frustules to chrysophycean statospores: A useful paleolimnological index , 1985, Hydrobiologia.

[44]  R. E. Turner,et al.  Global patterns of dissolved N, P and Si in large rivers , 2003 .

[45]  Ronald G. Rada,et al.  Recent influxes of metals into Lake Pepin, a natural lake on the Upper Mississippi River , 1990, Archives of environmental contamination and toxicology.

[46]  D. F. Grigal,et al.  Mobility and diagenesis of Pb and 210Pb in peat , 1990 .

[47]  P. Reimer,et al.  Extended 14C Data Base and Revised CALIB 3.0 14C Age Calibration Program , 1993, Radiocarbon: An International Journal of Cosmogenic Isotope Research.

[48]  Peter G. Appleby,et al.  Chronostratigraphic Techniques in Recent Sediments , 2002 .

[49]  Frank Oldfield,et al.  The calculation of lead-210 dates assuming a constant rate of supply of unsupported 210Pb to the sediment , 1978 .

[50]  E. Haworth Diatom Succession in a Core from Pickerel Lake, Northeastern South Dakota , 1972 .

[51]  F. Oldfield,et al.  Sediment source variations and lead-210 inventories in recent Potomac Estuary sediment cores , 2010 .

[52]  W. J. Andrews,et al.  Water-quality assessment of part of the Upper Mississippi River basin, Minnesota and Wisconsin, environmental setting and study design , 1996 .

[53]  N. Rabalais,et al.  Stoichiometric nutrient balance and origin of coastal eutrophication , 1995 .

[54]  N. Rabalais,et al.  Beyond Science into Policy: Gulf of Mexico Hypoxia and the Mississippi River , 2002 .

[55]  P. Glaser,et al.  Piston corers for peat and lake sediments , 1984 .

[56]  J. Zumberge Bulletin No. 35. The Lakes of Minnesota Their Origin and Classification , 1953 .

[57]  Walter E. Dean,et al.  Determination of carbonate and organic matter in calcareous sediments and sedimentary rocks by loss on ignition; comparison with other methods , 1974 .

[58]  M. Stuiver,et al.  High-Precision Bidecadal Calibration of the Radiocarbon Time Scale, AD 1950–500 BC and 2500–6000 BC , 1993, Radiocarbon.

[59]  B. Moss Further studies on the palaeolimnology and changes in the phosphorus budget of Barton Broad, Norfolk , 1980 .

[60]  J. Bradbury Diatom stratigraphy and human settlement in Minnesota , 1975 .

[61]  R. Hall,et al.  An expanded weighted-averaging model for inferring past total phosphorus concentrations from diatom assemblages in eutrophic British Columbia (Canada) lakes , 1995 .

[62]  John P. Smol,et al.  Tracking Environmental Change Using Lake Sediments: Data Handling and Numerical Techniques , 2001 .

[63]  D. Mulla,et al.  Historical trends affecting accumulation of sediment and phosphorus in Lake Pepin, upper Mississippi River, USA , 2009 .

[64]  Stephen Juggins,et al.  Lake surface-water chemistry reconstructions from palaeolimnological data. , 1990 .

[65]  D. Engstrom,et al.  Chemical stratigraphy of lake sediments as a record of environmental change , 1984 .

[66]  N. Anderson,et al.  Reconstructing historical phosphorus concentrations in rural lakes using diatom models. , 1997 .

[67]  L. Lijklema,et al.  Fractionation of inorganic phosphates in calcareous sediments. , 1980 .

[68]  R. D. Evans,et al.  Measurement of Whole Lake Sediment Accumulation and Phosphorus Retention Using Lead-210 Dating , 1980 .

[69]  W. Wiseman,et al.  Comparison of continuous records of near-bottom dissolved oxygen from the hypoxia zone along the Louisiana coast , 1994 .

[70]  Ronald G. Rada,et al.  Volume loss and mass balance for selected physicochemical constituents in Lake Pepin, upper Mississippi River, USA , 1995 .

[71]  G. Fahnenstiel,et al.  Biologically induced calcite and its isotopic composition in Lake Ontario , 1998 .

[72]  N. Anderson,et al.  Reconstruction of lake phosphorus loading and dynamics using the sedimentary record , 1996 .

[73]  Martin W. Marsden,et al.  Lake restoration by reducing external phosphorus loading: the influence of sediment phosphorus release , 1989 .

[74]  P. Brezonik,et al.  Modern and historic accumulation rates of phosphorus in Lake Okeechobee, Florida , 1998 .