Wastewater and Watershed Influences on Primary Productivity and Oxygen Dynamics in the Lower Hudson River Estuary

doi:10.1017/CBO9780511550539.012

10 - Wastewater and Watershed Influences on Primary Productivity and Oxygen Dynamics in the Lower Hudson River Estuary

Published online by Cambridge University Press: 06 January 2010

Robert W. Howarth ,

Roxanne Marino ,

Dennis P. Swaney and

Elizabeth W. Boyer

Edited by

Jeffrey S. Levinton and

John R. Waldman

Show author details

Robert W. Howarth: Affiliation:
Department of Ecology and Evolutionary Biology, Cornell University
Roxanne Marino: Affiliation:
Department of Ecology and Evolutionary Biology, Cornell University
Dennis P. Swaney: Affiliation:
Department of Ecology and Evolutionary Biology, Cornell University
Elizabeth W. Boyer: Affiliation:
Department of Environmental Science, Policy, and Management, University of California
Jeffrey S. Levinton: Affiliation:
State University of New York, Stony Brook

Book contents

Get access

Summary

abstract Primary productivity in the saline Hudson River estuary is strongly regulated by water residence times in the estuary. Nutrient loads and concentrations are very high, and when residence times are more than two days, production is extremely high. When water residence times are less than two days, production rates are low to moderate. Residence times are controlled both by freshwater discharge into the estuary and by tidal mixing, so residence times are longest and production is highest during neap tides when freshwater discharge is low. Freshwater discharge was generally high in the 1970s, which kept primary production low. In contrast, freshwater discharge rates were lower in the 1990s, and the estuary became hypereutrophic.

Nutrient loading per area of estuary to the saline portion of the Hudson is probably the highest for any major estuary in North America. As of the 1990s, approximately 58 percent of the nitrogen and 81 percent of the phosphorus came from wastewater effluent and other urban discharges in the New York City metropolitan area. Some 42 percent of the nitrogen and 19 percent of the phosphorus came from upriver tributary sources. For nitrogen, these tributary inputs are dominated by nonpoint sources, with atmospheric deposition from fossil fuel combustion and agricultural sources contributing equally. Human activity has probably increased nitrogen loading to the Hudson estuary twelve-fold and phosphorus loading fifty-fold or more since European settlement. Nitrogen and phosphorus loadings to the estuary have decreased somewhat since 1970 due to universal secondary treatment of dry-weather wastewater effluents and a ban on phosphates in detergents.

Type: Chapter
Information: The Hudson River Estuary , pp. 121 - 139

DOI: https://doi.org/10.1017/CBO9780511550539.012 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2006

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Banse, K. 1976. Rates of growth, respiration and photosynthesis of unicellular algae as related to cell size: a review. Journal of Phycology 12: 135–40Google Scholar

Billen, G., Somville, M., Becker, E., and Servais, P. 1985. A nitrogen budget of the Scheldt hydrographical basin. Netherlands Journal of Sea Research 19: 223–30CrossRef Google Scholar

Boyer, E. W., Goodale, C. L., Jaworski, N. A., and Howarth, R. W. 2002. Anthropogenic nitrogen sources and relationships to riverine nitrogen export in the northeastern USA. Biogeochemistry 57/58: 137–69CrossRef Google Scholar

Boynton, W. R., Garber, J. H., Summers, R., and Kemp, W. M. 1995. Inputs, transformations, and transport of nitrogen and phosphorus in Chesapeake Bay and selected tributaries. Estuaries 18: 285–314CrossRef Google Scholar

Bricker, S. B., Clement, C. G., Pirhalla, D. E., Orland, S. P., and Farrow, D. G. G. 1999. National Estuarine Eutrophication Assessment: Effects of Nutrient Enrichment in the Nation's Estuaries. Special Projects Office and the National Centers for Coastal Ocean Science, National Ocean Service, National Oceanic and Atmospheric Administration, Silver Spring, MDGoogle Scholar

Brosnan, T. M. and O'Shea, M. L. 1996. Long-term improvements in water quality due to sewage abatement in the lower Hudson River. Estuaries 19: 890–900CrossRef Google Scholar

Chan, F. A. 2001. “Ecological controls on planktonic nitrogen-fixation: the roles of grazing and cross-ecosystem patterns in phytoplankton mortality.” Ph. D. thesis, Cornell University, Ithaca, NY

Clark, J. F., Simpson, H. J., Bopp, R. F., and Deck, B. L. 1992. Geochemistry and loading history of phosphate and silicate in the Hudson estuary. Estuarine and Coastal Shelf Science 34: 213–33CrossRef Google Scholar

Clark, J.F, Simpson, H. J., Bopp, R. F., and Deck, B. L. 1995. Dissolved oxygen in lower Hudson estuary: 1978–1993. Journal of Environmental Engineering 121(10): 760–3CrossRef Google Scholar

Cloern, J. E. 2001. Our evolving conceptual model of the coastal eutrophication problem. Marine Ecology Progress Series 210: 223–53CrossRef Google Scholar

DEP (Department of Environmental Protection). 2001. New York City 2000 Regional Harbor Survey. New York City Department of Environmental Protection, NY

EPA (Environmental Protection Agency). 2001. Nutrient Criteria Technical Guidance Manual: Estuarine and Coastal Marine Waters. EPA-822-B-01–003, Office of Water, Washington, DC

Frithsen, J. B., Keller, A. A., and Pilson, M. E. Q. 1985. Effects of Inorganic Nutrient Additions in Coastal Areas: A Mesocosm Experiment Data Report, Vol. 1. Marine Ecosystem Research Laboratory, Report 3, University of Rhode Island, Kingston, RIGoogle Scholar

Garside, C., Malone, T. C., Roels, O. A., and Sharfstein, B. A. 1976. An evaluation of sewage-derived nutrients and their influence on the Hudson estuary and New York Bight. Estuarine and Coastal Marine Science 4: 281–9CrossRef Google Scholar

Gordon, Jr., D. C., Boudreau, P. R., Mann, K. H., Ong, J.-E., Silvert, W. L., Smith, S. V., Wattayakorn, G., Wulff, F., and Yanagi, T. 1996. LOICZ Biogeochemical Modeling Guidelines. LOICZ Reports & Studies No 5, 1–96. IGBP, Stockholm

Hetling, L. J., Stoddard, A., Brosnan, T. M., Hammerman, D. A., and Norris, T. M. 2003. Effect of water quality management efforts on wastewater loadings over the past center. Water Environment Research 75: 30–8CrossRef Google Scholar

Holland, E. A., Dentener, F. J., Braswell, B. H., and Sulzman, J. M. 1999. Contemporary and pre-industrial global reactive nitrogen budgets. Biogeochemistry 46: 7–43CrossRef Google Scholar

Howarth, R. W. 1998. An assessment of human influences on inputs of nitrogen to the estuaries and continental shelves of the North Atlantic Ocean. Nutrient Cycling in Agroecosystems 52: 213–23CrossRef Google Scholar

Howarth, R. W., Anderson, D., Cloern, J., Elfring, C., Hopkinson, C., Lapointe, B., Malone, T., Marcus, N., McGlathery, K., Sharpley, A., and Walker, D. 2000. Nutrient pollution of coastal rivers, bays, and seas. Issues in Ecology 7: 1–15Google Scholar

Howarth, R. W., Billen, G., Swaney, D., Townsend, A., Jaworski, N., Lajtha, K., Downing, J. A., Elmgren, R., Caraco, N., Jordan, T., Berendse, F., Freney, J., Kuteyarov, V., Murdoch, P., and Zhao-liang, Zhu. 1996b. Riverine inputs of nitrogen to the North Atlantic Ocean: Fluxes and human influences. Biogeochemistry 35: 75–139CrossRef Google Scholar

Howarth, R. W., Fruci, J. R., and Sherman, D. M. 1991. Inputs of sediment and carbon to an estuarine ecosystem: Influence of land use. Ecological Applications 1: 27–39CrossRef Google Scholar

Howarth, R. W., Jensen, H., Marino, R., and Postma, H. 1995. Transport to and processing of P in near-shore and oceanic waters, in Tiessen, H. (ed.), Phosphorus in the Global Environment: Transfers, Cycles, and Management. Chichester, UK: Wiley, pp. 323–45Google Scholar

Howarth, R. W., and Michaels, A. F. 2000. The measurement of primary production in aquatic ecosystems, in Sala, O., Jackson, R., Mooney, H., and Howarth, R. W. (eds.), Methods in Ecosystem Science, NY: Springer, pp. 72–85CrossRef Google Scholar

Howarth, R. W., Schneider, R., and Swaney, D. 1996a. Metabolism and organic carbon fluxes in the tidal, freshwater Hudson River. Estuaries 19: 848–65CrossRef Google Scholar

Howarth, R. W., Swaney, D., Butler, T. J., and Marino, R. 2000. Climatic control on eutrophication of the Hudson River estuary. Ecosystems 3: 210–215CrossRef Google Scholar

Jaworski, N. A., Howarth, R. W., and Hetling, L. J. 1997. Atmospheric deposition of nitrogen oxides onto the landscape contributes to coastal eutrophication in the northeast United States. Environmental Science and Technology 31: 1995–2004CrossRef Google Scholar

Lampman, G. G., Caraco, N. F., and Cole, J. J. 1999. Spatial and temporal patterns of nutrient concentration and export in the tidal Hudson River. Estuaries 22: 285–96CrossRef Google Scholar

Lewis, W. M. 2002. Yield of nitrogen from minimally disturbed watersheds in the United States. Biogeochemistry 57/58: 375–85CrossRef Google Scholar

Limburg, K. E., Moran, A., and McDowell, W. H. 1986. The Hudson River Ecosystem. NY: Springer-VerlagCrossRef Google Scholar

Malone, T. C. 1977. Environmental regulation of phytoplankton productivity in the lower Hudson estuary. Estuarine and Coastal Shelf Science 5: 157–71CrossRef Google Scholar

Malone, T. C. 1980. Algal size in Morris, I. (ed.), The Physiological Ecology of Phytoplankton. Oxford, UK: Blackwell, pp. 433–63Google Scholar

Malone, T. C., and Conley, D. J. 1996. Trends in nutrient loading and eutrophication: A comparison of the Chesapeake Bay and the Hudson River Estuarine Systems, in Sherman, K., Jaworski, N. A., and Smayda, T. J. (eds.), The Northeast Shelf Ecosystems: Assessment, Sustainability, and Management. Oxford UK: Blackwell, pp. 327–49Google Scholar

Mearns, A. J., Haines, E., Klepple, G. S., McGrath, R. A., McLaughlin, J. J. A., Segar, D. A., Sharp, J. H., Walsh, J. J., Word, J. Q., Young, D. K., and Young, M. W. 1982. Effects of nutrients and carbon loadings on communities and ecosystems, in Mayer, G. F. (ed.), Ecological Stress and the New York Bight: Science and Management. Estuarine Research Federation, Columbia, SC. pp. 53–65Google Scholar

Nixon, S. W. 1995. Coastal marine eutrophication: a definition, social causes, and future concerns. Ophelia 41: 199–219CrossRef Google Scholar

Nixon, S. W., Ammerman, J. W., Atkinson, L. P., Berounsky, V. M., Billen, G., Boicourt, W. C., Boynton, W. R., Church, T. M., DiToro, D. M., Elmgren, R., Garber, J. H., Giblin, A. E., Jahnke, R. A., Owens, N. J. P., Pilson, M. E. Q., and Seitzinger, S. P. 1996. The fate of nitrogen and phosphorus at the land-sea margin of the North Atlantic Ocean. Biogeochemistry 35: 141–80CrossRef Google Scholar

Nixon, S. W., and Pilson, M. E. Q. 1983. Nitrogen in estuarine and coastal marine ecosystems, in Carpenter, E. J., and Capone, D. G. (eds.), Nitrogen in the Marine Environment. New York: Academic Press, pp. 565–648Google Scholar

NRC (National Research Council). 1993. Managing Wastewater in Coastal Urban Areas. Washington, DC: National Academy of Sciences Press

NRC (National Research Council). 2000. Clean Coastal Waters: Understanding and Reducing the Effects of Nutrient Pollution. Washington, DC: National Academy of Sciences Press

O'Reilly, J. E., Thomas, J. P., and Evans, C. 1976. Annual primary production (nanoplankton, netplankton, dissolved organic matter) in the lower New York Bay. Paper #19 in Hudson River Ecology, 4th Symposium. Hudson River Environmental Society, Bronx, NYGoogle Scholar

Scavia, D., Field, J. C., Boesch, Buddemeier R., Burkett, V., Canyan, D., Fogarty, M., Harwell, M. A., Howarth, R. W., Mason, C., Reed, D. J., Royer, T. C., Sallenger, A. H., and Titus, J. G. 2002. Climate change impacts on US Coastal and marine ecosystems. Estuaries 25: 149–64CrossRef Google Scholar

Sirois, D. L., and Fredrick, S. W. 1978. Phytoplankton and primary production in the lower Hudson River estuary. Estuarine and Coastal Marine Science 5: 57–171Google Scholar

Suszkowski, D. J. 1990. Conditions in New York/New Jersey Harbor Estuary, in Proceedings of Cleaning Up Our Coastal Waters: An Unfinished Agenda. Manhattan College, Riverdale, NY, pp. 105–31Google Scholar

Swaney, D. P., Howarth, R. W., and Butler, T. J. 1999. A novel approach for estimating ecosystem production and respiration in estuaries: application to the oligohaline and mesohaline Hudson River estuary. Limnology and Oceanography 44: 1509–21CrossRef Google Scholar

Swaney, D. P., Sherman, D., and Howarth, R. W. 1996. Modeling water, sediment, and organic carbon discharges in the Hudson-Mohawk Basin: coupling to terrestrial sources. Estuaries 19: 833–47CrossRef Google Scholar

Taylor, G. T., Way, J., and Scranton, M. I. 2003. Planktonic carbon cycling and transport in surface waters of the highly urbanized Hudson River estuary. Limnology and Oceanography 48: 1779–95CrossRef Google Scholar

U.S. Census Bureau. 2002. 2000 Census of Population and Housing. Economics and Statistics Administration, U.S. Department of Commerce. [online] url: http://www.census.gov/dmd/www/2khome.htm

USGS (United States Geological Survey). 2002. National Water-Quality Assessment (NAWQA) Study-Unit Investigations in the conterminous United States: Watershed Boundaries. [online] url: http://water.usgs.gov/GIS/

Book contents

10 - Wastewater and Watershed Influences on Primary Productivity and Oxygen Dynamics in the Lower Hudson River Estuary

Summary

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive