Riverine discharges to Chesapeake Bay: Analysis of long-term (1927–2014) records and implications for future flows in the Chesapeake Bay basin

Riverine discharges to Chesapeake Bay: Analysis of long-term (1927–2014) records and... The Chesapeake Bay (CB) basin is under a total maximum daily load (TMDL) mandate to reduce nitrogen, phosphorus, and sediment loads to the bay. Identifying shifts in the hydro-climatic regime may help explain observed trends in water quality. To identify potential shifts, hydrologic data (1927–2014) for 27 watersheds in the CB basin were analyzed to determine the relationships among long-term precipitation and stream discharge trends. The amount, frequency, and intensity of precipitation increased from 1910 to 1996 in the eastern U.S., with the observed increases greater in the northeastern U.S. than the southeastern U.S. The CB watershed spans the north-to-south gradient in precipitation increases, and hydrologic differences have been observed in watersheds north relative to watersheds south of the Pennsylvania—Maryland (PA-MD) border. Time series of monthly mean precipitation data specific to each of 27 watersheds were derived from the Precipitation-elevation Regression on Independent Slopes Model (PRISM) dataset, and monthly mean stream-discharge data were obtained from U.S. Geological Survey streamgage records. All annual precipitation trend slopes in the 18 watersheds north of the PA-MD border were greater than or equal to those of the nine south of that border. The magnitude of the trend slopes for 1927–2014 in both precipitation and discharge decreased in a north-to-south pattern. Distributions of the monthly precipitation and discharge datasets were assembled into percentiles for each year for each watershed. Multivariate correlation of precipitation and discharge within percentiles among the groups of northern and southern watersheds indicated only weak associations. Regional-scale average behaviors of trends in the distribution of precipitation and discharge annual percentiles differed between the northern and southern watersheds. In general, the linkage between precipitation and discharge was weak, with the linkage weaker in the northern watersheds compared to those in the south. On the basis of simple linear regression, 26 of the 27 watersheds are projected to have higher annual mean discharge in 2025, the target date for implementation of the TMDL for the CB basin. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Journal of Environmental Management Elsevier

Riverine discharges to Chesapeake Bay: Analysis of long-term (1927–2014) records and implications for future flows in the Chesapeake Bay basin

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Publisher
Elsevier
Copyright
Copyright © 2017 Elsevier Ltd
ISSN
0301-4797
D.O.I.
10.1016/j.jenvman.2017.08.057
Publisher site
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Abstract

The Chesapeake Bay (CB) basin is under a total maximum daily load (TMDL) mandate to reduce nitrogen, phosphorus, and sediment loads to the bay. Identifying shifts in the hydro-climatic regime may help explain observed trends in water quality. To identify potential shifts, hydrologic data (1927–2014) for 27 watersheds in the CB basin were analyzed to determine the relationships among long-term precipitation and stream discharge trends. The amount, frequency, and intensity of precipitation increased from 1910 to 1996 in the eastern U.S., with the observed increases greater in the northeastern U.S. than the southeastern U.S. The CB watershed spans the north-to-south gradient in precipitation increases, and hydrologic differences have been observed in watersheds north relative to watersheds south of the Pennsylvania—Maryland (PA-MD) border. Time series of monthly mean precipitation data specific to each of 27 watersheds were derived from the Precipitation-elevation Regression on Independent Slopes Model (PRISM) dataset, and monthly mean stream-discharge data were obtained from U.S. Geological Survey streamgage records. All annual precipitation trend slopes in the 18 watersheds north of the PA-MD border were greater than or equal to those of the nine south of that border. The magnitude of the trend slopes for 1927–2014 in both precipitation and discharge decreased in a north-to-south pattern. Distributions of the monthly precipitation and discharge datasets were assembled into percentiles for each year for each watershed. Multivariate correlation of precipitation and discharge within percentiles among the groups of northern and southern watersheds indicated only weak associations. Regional-scale average behaviors of trends in the distribution of precipitation and discharge annual percentiles differed between the northern and southern watersheds. In general, the linkage between precipitation and discharge was weak, with the linkage weaker in the northern watersheds compared to those in the south. On the basis of simple linear regression, 26 of the 27 watersheds are projected to have higher annual mean discharge in 2025, the target date for implementation of the TMDL for the CB basin.

Journal

Journal of Environmental ManagementElsevier

Published: Dec 15, 2017

References

  • Hydroclimatic flood trends in the northeastern United States and linkages with large-scale atmospheric circulation patterns
    Armstrong, W.H.; Collins, M.J.; Snyder, N.P.
  • A precipitation shift from snow towards rain leads to a decrease in streamflow
    Berghuijs, W.R.; Woods, R.A.; Hrachowitz, M.
  • Dominant flood generating mechanisms across the United States
    Berghuijs, W.R.; Woods, R.A.; Hutton, C.J.; Sivapalan, M.
  • A comparative analysis of nutrients and other factors influencing estuarine phytoplankton production
    Boynton, W.R.; Kemp, W.M.; Keefe, C.W.
  • Effects of nutrient enrichment in the nation's estuaries: a decade of change
    Bricker, S.B.; Longstaff, B.; Dennison, W.; Jones, A.; Boicourt, K.; Wicks, C.; Woerner, J.
  • Physiographically sensitive mapping of temperature and precipitation across the conterminous United States
    Daly, C.; Halbleib, M.; Smith, J.I.; Gibson, W.P.; Doggett, M.K.; Taylor, G.H.; Curtis, J.; Pasteris, P.A.
  • Trends in seasonal river flow regimes in the UK
    Hannaford, J.; Buys, G.
  • Has the magnitude of floods across the USA changed with global CO2 levels?
    Hirsch, R.M.; Ryberg, K.R.
  • Changes in the timing of winter-spring streamflows in eastern North America, 1913-2002
    Hodgkins, G.A.; Dudley, R.W.
  • Examining why trends in very heavy precipitation should not be mistaken for trends in very high river discharge
    Ivancic, T.J.; Shaw, S.B.
  • Secular trends of precipitation amount, frequency, and intensity in the United States
    Karl, T.R.; Knight, R.W.
  • Global Climate Change Impacts in the United States
    Karl, T.R.; Melillo, J.M.; Peterson, T.C.
  • Climate Change Impacts in the United States: the Third National Climate Assessment
    Melillo, J.M.; Richmond, T.C.; Yohe, G.W.
  • Stationarity is dead: whither water management?
    Milly, P.C.D.; Betancourt, J.; Falkenmark, M.; Hirsch, R.; Kundzewicz, Z.W.; Lettenmaier, D.P.; Stouffer, R.J.
  • On critiques of “stationarity is dead: whither water management?,”
    Milly, P.C.D.; Betancourt, J.; Falkenmark, M.; Hirsch, R.M.; Kundzewicz, Z.W.; Lettenmaier, D.P.; Stouffer, R.J.; Dettinger, M.D.; Krysanova, V.
  • Modeling and mitigating natural hazards: stationarity is immortal!
    Montanari, A.; Koutsoyiannis, D.
  • Spatial and Temporal Trends in Runoff at Long-term Streamgages within and Near the Chesapeake Bay Watershed, USGS Scientific Investigations Report 2012-5151
    Rice, K.C.; Hirsch, R.M.
  • Changes in Center Time of Spring Discharge and Precipitation in Chesapeake Bay Watershed, 1927-2012
    Rice, K.C.; Milly, P.C.D.; Wolock, D.M.
  • A study of national trend and variation in UK floods
    Robson, A.J.; Jones, T.K.; Reed, D.W.; Bayliss, A.C.
  • Trends in precipitation and streamflow in the eastern U.S.: paradox or perception?
    Small, D.; Islam, S.; Vogel, M.
  • Analysis of long-term trends (1950-2009) in precipitation, runoff and runoff coefficient in major urban watersheds in the United States
    Velpuri, N.M.; Senay, G.B.
  • Nonstationarity: flood magnification and recurrence reduction factors in the United States
    Vogel, R.M.; Yaindl, C.; Walter, M.
  • Analysis of water resources variability in the Yellow River of China during the last half century using historical data
    Yang, D.; Li, C.; Hu, H.; Lei, Z.; Yang, S.; Kusuda, T.; Koike, T.; Musiake, K.

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