Estimating Relevance of Organic Carbon, Nitrogen, and Phosphorus Loads to a Blackwater River Estuary1
John Hendrickson,
Nadine Trahan,
Emily Gordon,
Ying Ouyang,
John Hendrickson
(Hendrickson) Environmental Scientist V, St. Johns River Water Management District, P. O. Box 1429, Palatka, Florida 32178-1429
Search for more papers by this authorNadine Trahan
(Trahan) GIS Analyst, Jones, Edmunds & Assoc., Gainesville, Florida 32641, USA
Search for more papers by this authorEmily Gordon
(Gordon, Ouyang) Environmental Scientist I and Environmental Scientist IV, BCI Engineers and Scientists, Lakeland, Florida 33807-5467
Search for more papers by this authorYing Ouyang
(Gordon, Ouyang) Environmental Scientist I and Environmental Scientist IV, BCI Engineers and Scientists, Lakeland, Florida 33807-5467
Search for more papers by this authorJohn Hendrickson,
Nadine Trahan,
Emily Gordon,
Ying Ouyang,
John Hendrickson
(Hendrickson) Environmental Scientist V, St. Johns River Water Management District, P. O. Box 1429, Palatka, Florida 32178-1429
Search for more papers by this authorNadine Trahan
(Trahan) GIS Analyst, Jones, Edmunds & Assoc., Gainesville, Florida 32641, USA
Search for more papers by this authorEmily Gordon
(Gordon, Ouyang) Environmental Scientist I and Environmental Scientist IV, BCI Engineers and Scientists, Lakeland, Florida 33807-5467
Search for more papers by this authorYing Ouyang
(Gordon, Ouyang) Environmental Scientist I and Environmental Scientist IV, BCI Engineers and Scientists, Lakeland, Florida 33807-5467
Search for more papers by this author(E-Mail/Hendrickson: [email protected]).
1
Paper No. J05107 of the Journal of the American Water Resources Association (JAWRA).
Abstract
Abstract: In blackwater river estuaries, a large portion of external carbon, nitrogen, and phosphorus load are combined in complex organic molecules of varying recalcitrance. Determining their lability is essential to establishing the relationship between anthropogenic loads and eutrophication. A method is proposed in which organic C, N, and P are partitioned into labile and refractory forms, based upon first-order decay estimated by biochemical oxygen demand relative to total organic carbon, and C:N and C:P ratios as a function of organic carbon lability. The technique was applied in developing total maximum daily loads for the lower St. Johns, a blackwater Atlantic coastal plain river estuary in Northeast Florida. Point source organic nutrients were determined to be largely labile. Urban runoff was found to have the highest relative labile organic N and P content, followed by agricultural runoff. Natural forest and silviculture runoff were high in refractory organic N and P. Upstream labile C, N, and P loads were controlled by autochthonous production, with 34-50% of summer total labile carbon imported as algal biomass. Differentiation of labile and refractory organic forms suggests that while anthropogenic nutrient enrichment has tripled the total nitrogen load, it has resulted in a 6.7-fold increase in total labile nitrogen load.
Literature cited
- Adamus, C.L. and M.J. Bergman, 1995. Estimating Nonpoint Source Pollutant Loads With a GIS Screening Model. Water Res. Bull. 31(4): 647-655.
-
Aitkenhead-Peterson, J.A.,
W.H. McDowell, and J.C. Neff, 2003. Sources, Production and Regulation of Allochthonous Dissolved Organic Matter Inputs to Surface Waters. In: Aquatic Ecosystems: Interactivity of Dissolved Organic Matter, S.E.G. Findlay and
R.L. Sinsabaugh (Editors). Academic Press, San Diego, California, pp. 26-70.
10.1016/B978-012256371-3/50003-2 Google Scholar
- Anderson, L.A, 1995. On the Hydrogen and Oxygen Content of Marine Phytoplankton. Deep-Sea Research 42: 1675-1680.
- Bertilsson, S. and L.J. Tranvik, 2000. Photochemical Transformation of Dissolved Organic Matter in Lakes. Limnology and Oceanography 45(4): 753-762.
- Boynton, W.R., J.H. Garber, R. Summers, and W.M. Kemp, 1995. Inputs, Transformations and Transport of Nitrogen and Phosphorus in Chesapeake Bay and Selected Tributaries. Estuaries 18(1B): 285-314.
- Bushaw, K.L., R.G. Zepp, M.A. Tarr, D. Schulz-Jander, R.A. Bourbonniere, R.E. Hodson, W.L. Miller, D.A. Bronk and M-A. Moran, 1996. Photochemical Release of Bilogically Available Nitrogen From Dissolved Organic Matter. Nature 381: 404-407.
- Cerco, C. F. and T. Cole, 1993. Three Dimensional Eutrophication Model of Chesapeake Bay. Journal of Environmental Engineering 119: 1006-1025.
- Chapra, S.C., 1997. Surface Water Quality Modeling. McGraw Hill, New York, 844 pp.
- Cifuentes, L.A. and P.M. Eldridge, 1998. A Mass- and Isotope-Balance Model of DOC Mixing in Estuaries. Limnology and Oceanography 43(8): 1872-1882.
- Clinton, S.M., R.T. Edwards, and R.J. Naiman, 2002. Forest-River Interactions: Influence on Hyporheic Dissolved Organic Carbon Concentrations in a Floodplain Terrace. Journal of the American Water Resources Association 38(3): 619-631.
- Cuthbert, I.D. and P. Del Giorgio, 1992. Toward a Standard Method of Measuring Color in Freshwater. Limnology and Oceanography 37(6): 1319-1326.
- DeBusk, W.F., J.R. White, and K.R. Reddy, 2001. Carbon and Nitrogen Dynamics in Wetland Soils. In: Modeling Carbon and Nitrogen Dynamics for Soil Management, M.J. Shaffer, L. Ma, and S. Hansen (editors). Lewis Publishers, Boca Raton, Florida. pp. 27-53.
- Diaz, A.O., K.R. Reddy, and P.A. Moore Jr, 1994. Solubility of Inorganic Phosphorus in Stream Water as Influenced by pH and Calcium Concentration. Water Research 28: 1755-1763.
- Fagerbakke, K.M., M. Heldal, and S. Norland, 1996. Content of Carbon, Nitrogen, Oxygen, Sulfur and Phosphorus in Native Aquatic and Cultured Bacteria. Aquatic Microbiology and Ecology 10: 15-27.
- Foreman, C.M., P. Franchini, and R.L. Sinsabaugh, 1998. The Trophic Dynamics of Riverine Bacterioplankton: Relationships Among Substrate Availability, Ectoenzyme Kinetics, and Growth. Limnology and Oceanography 43(6): 1344-1352.
- Gao, H. and R.G. Zepp, 1998. Factors Influencing Photoreactions of Dissolved Organic Matter in a Coastal River of the Southeastern United States. Environmental Science and Technology 32(19): 2940-2946.
- Goldman, J.C., D.A. Caron, and M.R. Dennett, 1987. Regulation of Gross Growth Efficiency and Ammonium Regeneration in Bacteria by Substrate C:N Ratio. Limnology and Oceanography 32(6): 1239-1252.
- Goolsby, D.A., W.A. Battaglin, B.T. Aulenbach, and R.P. Hooper, 2001. Nitrogen Input to the Gulf of Mexico. J. Environ. Qual. 30: 329-336.
- Graves, G.A., Y. Wan, and D.L. Fike, 2004. Water Quality Characteristics of Stormwater From Land Uses in South Florida. Journal of the American Water Resources Association 40(6): 1405-1419.
- Greenberg, A.E., L.S. Clesceri, and A.D. Eaton, 1992. Standard Methods for the Examination of Water and Wastewater, (Eighteenth Edition), American Public Health Association, Washington, District of Columbia.
- Jaworski, N.A., P.M. Groffman, A.A. Keller, and J.C. Prager, 1992. A Watershed Nitrogen and Phosphorus Balance: The Upper Potomac River Basin. Estuaries 15(1): 83-95.
- Jewell, W.J. and P.L. McCarty, 1971. Aerobic Decomposition of Algae. Environmental Science and Technology 5(10): 1023-1031.
- Kaplan, L.A. and J.D. Newbold, 1995. Measurement of Streamwater Biodegradable Dissolved Organic Carbon With a Plug-Flow Bioreactor. Water Research 29: 2696-2706.
- Kirchman, D.L., 2000. Uptake and Regeneration of Organic Nutrients by Marine Heterotrophic Bacteria. In: Microbial Ecology of the Oceans, D.L. Kirchman (Editor), Wiley, New York, pp. 261-288.
- Kroer, N., 1993. Bacterial Growth Efficiency on Natural Dissolved Organic Matter. Limnology and Oceanography 38: 1282-1290.
- Magnien, R.E., R.M. Summers, and K.G. Sellner, 1992. External Nutrient Sources, Internal Nutrient Pools, and Phytoplankton Production in Chesapeake Bay. Estuaries 15(4): 497-516.
- Mann, K.H., 1988. Production and use of Detritus in Various Freshwater, Estuarine, and Coastal Marine Ecosystems. Limnology and Oceanography 33(4): 910-930.
- May, E.B., 1973. Extensive Oxygen Depletion in Mobile Bay, Alabama. Limnology and Oceanography 18(3): 353-366.
- McFarland, A.M.S. and L.M. Hauck, 2001. Determining Nutrient Export Coefficients and Source Loading Uncertainty Using in-Stream Monitoring Data. Journal of the American Water Resources Association 37(1): 223-236.
- McKnight, D.M., E.W. Boyer, P.K. Westerhoff, P.T. Doran, T. Kulbe, and D.T. Andersen, 2001. Spectrofluorometric Characterization of Dissolved Organic Matter for Indication of Precursor Organic Material and Aromaticity. Limnology and Oceanography 46(1): 38-48.
- Meyer, J.L., 1990. A Blackwater Perspective on Riverine Ecosystems. Bioscience 40(9): 643-651.
- Meyer, J.L. and R.T. Edwards, 1990. Ecosystem Metabolism and Turnover of Organic Carbon Along a Blackwater River Continuum. Ecology, 71(2): 668-677.
- Moran, M.A. and R.E. Hodson, 1989. Formation and Bacterial Utilization of Dissolved Organic Carbon Derived From Detrital Lignocellulose. Limnology and Oceanography 34(6): 1034-1047.
- Moran, M.A. and R.E. Hodson, 1990. Bacterial Production on Humic and Nonhumic Components of Dissolved Organic Carbon. Limnology and Oceanography 35(8): 1744-1756.
- Moran, M.A., W.M. Sheldon Jr, and J.E. Sheldon, 1999. Biodegradation of Riverine Dissolved Organic Carbon in Five Estuaries of the Southeastern United States. Estuaries 22(1): 55-64.
- National Research Council, 2000. Clean Coastal Waters: Understanding and Reducing the Effects of Nutrient Pollution. Ocean Studies Board and Water Science and Technology Board, Commission on Geosciences, Environment, and Resources, National Academy Press, Washington D.C., 405 pp.
- Nazarian, A.P., E.P. Simonds, and S.M. Dickerson, 2005. Water Resources Data Florida: Water Year 2004. Volume 1A. Northeast Florida Surface Water. U.S. Department of the Interior U.S. Geological Survey Report No. USGS/WDR-FL-04-1A. 397 pp.
- NCASI, 2004. Biodegradability of Organic Nitrogen and Phosphorus in Pulp Mill Effluents. Technical Bulletin No. 879. Research Triangle Park, N.C. National Council for Air and Stream Improvement, Inc., Research Triangle Park, North Carolina.
- Nixon, S.W., 1995. Coastal Marine Eutrophication: A Definition, Social Causes, and Future Concerns. Ophelia 41: 199-219.
- Officer, C.B., R.W. Biggs, J.L. Taft, L.E. Cronin, M.A. Tyler, and W.R. Boynton, 1984. Chesapeake bay Anoxia: Origin, Development and Significance. Science 223(1/6/84): 22-27.
- Ogura, N., 1975. Further Studies on Decomposition of Dissolved Organic Matter in Coastal Seawater. Marine Biology 31: 60-62.
- Osburn, C.L., H.E. Zagarese, D.P. Morris, B.R. Hargreaves, and W.R. Cravero, 2001. Calculation of the Spectral Weighting Functions for the Solar Photobleaching of Dissolved Organic Matter in Temperate Lakes. Limnology and Oceanography 46(6): 1455-1467.
- Paerl, H.W., J. Dyble, P.H. Moisander, and M.F. Piehler, 2003. The Effects of Changing Nutrient Conditions on the Structure and Function of the Phytoplankton of the Lower St. Johns River. University of North Carolina Institute of Marine Sciences, Morehead City, NC. Final Report Submitted to the St. Johns River Water Management District, Contract # SD154RA. Palatka, Florida.
- Phlips, E.J. and M.F. Cichra, 2001. Plankton Communities of the Lower St. Johns River. University of Florida Department of Fisheries and Aquatic Sciences, Gainesville, Florida. Annual Report to the St. Johns River Water Management District, Contract #97W165.
- Rasmussen, J.B., L. Godbout, and M. Schallenberg, 1989. The Humic Content of Lake Water and its Relationship to Watershed and Lake Morphometry. Limnology and Oceanography 34(7): 1336-1343.
- Raymond, P.A. and J.E. Bauer, 2001. DOC Cycling in a Temperate Estuary: A Mass Balance Approach Using Natural 14C and 13C Isotopes. Limnology and Oceanography 46(3): 655-667.
- Seitzinger, S.P. and R.W. Sanders, 1997. Contribution of Dissolved Organic Nitrogen From Rivers to Estuarine Eutrophication. Marine Ecology Progress Series 159: 1-12.
- Seitzinger, S.P., R.W. Sanders, and R. Styles, 2002. Bioavailability of DON From Natural and Anthropogenic Sources to Estuarine Phytoplankton. Limnology and Oceanography 47(2): 353-366.
- Sondergaard, M. and M. Middelboe, 1995. A Cross-System Analysis of Labile Dissolved Organic Carbon. Marine Ecology Progress Series 118: 283-294.
- Stepanauskas, R., L. Leonardson, and L.J. Tranvik, 1999. Bioavailability of Wetland Derived DON to Freshwater and Marine Bacterioplankton. Limnology and Oceanography 44(6): 1477-1485.
- Stepanauskas, R., H. Laudon, and N.O.G. Jorgensen, 2000. High DON Bioavailability in Boreal Streams During a Spring Flood. Limnology and Oceanography, 45(6): 1298-1307.
- Strauss, E.A. and G.A. Lamberti, 2000. Regulation of Nutrification in Aquatic Sediments by Organic Carbon. Limnology and Oceanography 45(8): 1854-1859.
- Strickland, J.D.H., 1960. Measuring the Production of Marine Phytoplankton. Bulletin of the Fisheries Research Board of Canada 122: 172 pp.
- Sucsy, P. and J.C. Hendrickson, 2004. Calculation of Nutrient Reduction Goals for the Lower St. Johns River by Application of CE-QUAL-ICM, a Mechanistic Water Quality Model. Water Resources Department Technical Memorandum, St. Johns River Water Management District, Palatka, Florida.
- Sun, L., E.M. Perdue, J.L. Meyer, and J. Weis, 1997. Use of Elemental Compostion to Predict Bioavailability of Dissolved Organic Matter in a Georgia River. Limnology and Oceanography 42(4): 714-721.
-
Thurman, E.M., 1985. Organic Geochemistry of Natural Waters. Kluwer Academic Publishers Group, Boston, Massachusetts, 497
pp.
10.1007/978-94-009-5095-5 Google Scholar
- Tufford, D.L., C.L. Samarghitan, H.N. McKellar Jr, D.E. Porter, and J.R. Hussey, 2003. Impacts of Urbanization on Nutrient Concentrations in Small Southeastern Coastal Streams. Journal of the American Water Resources Association 39(2): 301-312.
- Valiela, I., K. Foreman, M. LaMontagne, D. Hersh, J. Costa, P. Peckol, B. DeMeo-Andreson, C. D’Avanzo, M. Babione, C. Sham, J. Brawley, and K. Lajtha, 1992. Couplings of Watersheds and Coastal Waters: Sources and Consequences of Nutrient Enrichment in Waquiot Bay, Massachusetts. Estuaries 15(4): 443-457.
- Vannote, R.L., G.W. Minshall, K.W. Cummins, J.R. Sedell, and C.E. Cushing, 1980. The River Continuum Concept. Can. J. Fish. Aqu. Sci. 37: 130-137.
- Volk, C.J., C.B. Volk, and L.A. Kaplan, 1997. Chemical Composition of Biodegradable Dissolved Organic Matter in Streamwater. Limnology and Oceanography 42(1): 39-44.
- Wetzel, R.A. and G.E. Likens, 1990. Limnological Analyses, (Second Edition). Springer-Verlag, New York, 391 pp.
- Wetzel, R.G., 2003. Limnology: Lake and River Ecosystems, (Third Edition). Academic Press, San Diego, California, 1006 pp.
