Douglas A Burns (Former Employee)
Science and Products
Filter Total Items: 119
Target loads of atmospheric sulfur and nitrogen deposition for protection of acid sensitive aquatic resources in the Adirondack Mountains, New York
The dynamic watershed acid-base chemistry model of acidification of groundwater in catchments (MAGIC) was used to calculate target loads (TLs) of atmospheric sulfur and nitrogen deposition expected to be protective of aquatic health in lakes in the Adirondack ecoregion of New York. The TLs were calculated for two future dates (2050 and 2100) and three levels of protection against lake acidificatio
Authors
T.J. Sullivan, B.J. Cosby, C. T. Driscoll, T.C. McDonnell, A.T. Herlihy, Douglas A. Burns
TOPMODEL simulations of streamflow and depth to water table in Fishing Brook Watershed, New York, 2007-09
TOPMODEL, a physically based, variable-source area rainfall-runoff model, was used to simulate streamflow and depth to water table for the period January 2007-September 2009 in the 65.6 square kilometers of Fishing Brook Watershed in northern New York. The Fishing Brook Watershed is located in the headwaters of the Hudson River and is predominantly forested with a humid, cool continental climate.
Authors
Elizabeth A. Nystrom, Douglas A. Burns
Setting limits: Using air pollution thresholds to protect and restore US ecosystems
More than four decades of research provide unequivocal evidence that sulfur, nitrogen, and mercury pollution have altered, and will continue to alter, our nation's lands and waters. The emission and deposition of air pollutants harm native plants and animals, degrade water quality, affect forest productivity, and are damaging to human health. Many air quality policies limit emissions at the source
Authors
Mark E. Fenn, Kathleen F. Lambert, Tamara F. Blett, Douglas A. Burns, Linda H. Pardo, Gary M. Lovett, Richard A. Haeuber, David C. Evers, Charles T. Driscoll, Dean S. Jeffries
Spatial patterns of mercury in macroinvertebrates and fishes from streams of contrasting forested landscapes in the eastern United States
Controls on mercury bioaccumulation in lotic ecosystems are not well understood. During 2007–2009, we studied mercury and stable isotope spatial patterns of macroinvertebrates and fishes from two medium-sized (
Authors
Karen Riva-Murray, Lia C. Chasar, Paul M. Bradley, Douglas A. Burns, Mark E. Brigham, Martyn J. Smith, Thomas A. Abrahamsen
Spatial and seasonal variability of dissolved methylmercury in two stream basins in the Eastern United States
We assessed methylmercury (MeHg) concentrations across multiple ecological scales in the Edisto (South Carolina) and Upper Hudson (New York) River basins. Out-of-channel wetland/floodplain environments were primary sources of filtered MeHg (F-MeHg) to the stream habitat in both systems. Shallow, open-water areas in both basins exhibited low F-MeHg concentrations and decreasing F-MeHg mass flux. Do
Authors
Paul M. Bradley, Douglas A. Burns, Karen Riva-Murray, Mark E. Brigham, Daniel T. Button, Lia C. Chasar, Mark Marvin-DiPasquale, Mark A. Lowery, Celeste A. Journey
Effects of acid deposition on ecosystems: Advances in the state of the science
Chapter 2 focused on the environmental results of the ARP, presenting data from national monitoring networks on SO2 and NOx emissions, air quality, atmospheric deposition, surface water chemistry, and visibility. This chapter expands on this information by examining the most recent research into how ecosystems respond to acid deposition, especially the processes that control the recovery of ecosys
Authors
Douglas A. Burns, Mark E. Fenn, Jill Baron
Hydrological mobilization of mercury and dissolved organic carbon in a snow-dominated, forested watershed: Conceptualization and modeling
The mobilization of mercury and dissolved organic carbon (DOC) during snowmelt often accounts for a major fraction of the annual loads. We studied the role of hydrological connectivity of riparian wetlands and upland/wetland transition zones to surface waters on the mobilization of Hg and DOC in Fishing Brook, a headwater of the Adirondack Mountains, New York. Stream water total mercury (THg) conc
Authors
J. Schelker, Douglas A. Burns, M. Weiler, H. Laudon
The relation of harvesting intensity to changes in soil, soil water, and stream chemistry in a northern hardwood forest, Catskill Mountains, USA
Previous studies have shown that clearcutting of northern hardwood forests mobilizes base cations, inorganic monomeric aluminum (Alim), and nitrate (NO3--N) from soils to surface waters, but the effects of partial harvests on NO3--N have been less frequently studied. In this study we describe the effects of a series of partial harvests of varying proportions of basal area removal (22%, 28% and 68%
Authors
Jason Siemion, Douglas A. Burns, Peter S. Murdoch, Rene H. Germain
National Acid Precipitation Assessment Program Report to Congress: An integrated assessment
Acid deposition, more commonly known as acid rain, occurs when emissions of sulfur dioxide (SO2) and nitrogen oxides (NOx) react in the atmosphere with water, oxygen, and oxidants to form various acidic compounds. Prevailing winds transport the acidic compounds hundreds of miles, often across state and national borders. These acidic compounds then fall to earth in either a wet form (rain, snow, an
Authors
Douglas A. Burns, Mark E. Fenn, Jill Baron, Jason A. Lynch, Bernard J. Cosby
Environmental settings of streams sampled for mercury in New York and South Carolina, 2005-09
This report summarizes the environmental settings of streams in New York and South Carolina, where the U.S. Geological Survey completed detailed investigations during 2005-09 into factors contributing to mercury bioaccumulation in top-predator fish and other stream organisms. Descriptions of location, land use/land cover, climate, precipitation, atmospheric deposition, hydrology, water temperature
Authors
Barbara C. Scudder Eikenberry, Karen Riva-Murray, Martyn J. Smith, Paul M. Bradley, Daniel T. Button, Jimmy M. Clark, Douglas A. Burns, Celeste A. Journey
Setting limits: Using air pollution thresholds to protect and restore U.S. ecosystems
More than four decades of research provide unequivocal evidence that sulfur, nitrogen, and mercury pollution have altered, and will continue to alter, our nation's lands and waters. The emission and deposition of air pollutants harm native plants and animals, degrade water quality, affect forest productivity, and are damaging to human health. Many air quality policies limit emissions at the source
Authors
M.E. Fenn, K.F. Lambert, T.F. Blett, Douglas A. Burns, L.H. Pardo, Gary M. Lovett, R. A. Haeuber, D.C. Evers, C. T. Driscoll, D.S. Jeffries
Total mercury, methylmercury, and selected elements in soils of the Fishing Brook watershed, Hamilton County, New York, and the McTier Creek watershed, Aiken County, South Carolina, 2008
Mercury is an element of on-going concern for human and aquatic health. Mercury sequestered in upland and wetland soils represents a source that may contribute to mercury contamination in sensitive ecosystems. An improved understanding of mercury cycling in stream ecosystems requires identification and quantification of mercury speciation and transport dynamics in upland and wetland soils within a
Authors
Laurel G. Woodruff, William F. Cannon, Christopher D. Knightes, Francis H. Chapelle, Paul M. Bradley, Douglas A. Burns, Mark E. Brigham, Mark A. Lowery
Non-USGS Publications**
Harpold, A.A., Burns, D.A., Walter, T., Shaw, S.B., and Steenhuis, T.S., 2010, Relating hydrogeomorphologic properties to stream buffering chemistry in the Neversink River Watershed, New York State, USA, Hydrological Processes, 24: 3759-3771.
Vidon, P., Allan, C., Burns, D., Duval, T., Gurwick, N., Inamdar, S., Lowrance, R., Okay, J., Scott, D., Sebestyen, S., 2010, Hot spots and hot moments in riparian zones: Potential for improved water quality management, Journal of the American Water Resources Association, 46: 278-298.
Kerr, J.G., Eimers, M.C., Creed, I.F., Adams, M.B., Beall, F., Burns, D., Campbell, J.L., Christopher, S.F., Clair, T.A., Couchesne, F., Duchense, L., Fernandez, I., Houle, D., Jeffries, D.S., Likens, G.E., Mitchell, M.J., Shanley, J., Yao, H., 2012, The effect of seasonal drying on sulphate dynamics in streams across southeastern Canada and the northeastern USA, Biogeochemistry, 111: 393-409.
Burns, D.A., Blett, T., Haeuber, R., Pardo, L., 2008, Critical loads as a policy tool for protecting ecosystems from the effects of air pollutants, Frontiers of Ecology and the Environment, 6: 156-159.
Elliott, E.M., Kendall, C., Boyer, E.W., Burns, D.A., Wankel, S.D., Bain, D.J., Harlin, K., Butler, T.J., Carlton, R., 2007, An isotopic tracer of stationary source NOx emissions across the midwestern and northeastern United States, Environmental Science and Technology, 41: 7661-7667.
Burns, D.A., Plummer, L.N., McDonnell, J.J., Busenberg, E., Casile, G.C., Kendall, C., Hooper, R.P., Freer, J.E., Peters, N.E., Beven, K., and Schlosser, P., 2003, The geochemical evolution of groundwater in a forested Piedmont catchment, Ground Water, 41: 913-925.
Burns, D.A., and Nguyen, L., 2002, Nitrate movement and removal along a shallow groundwater flow path in a riparian wetland within a sheep-grazed pastoral catchment: results of a tracer study, New Zealand Journal of Marine and Freshwater Research, 36: 371-385.
Vitvar, T., Burns, D.A., Lawrence, G.B., McDonnell, J.J., and Wolock, D.M., 2002, Estimation of groundwater residence times in watersheds from the recession of the runoff-hydrograph: method and application in the Neversink watershed, Catskill Mountains, New York, Hydrological Processes, 16: 1871-1877.
Burns, D.A., Lawrence, G.B., and Murdoch, P.S., 1998, Catskill streams still susceptible to acid rain, Eos, Transactions, American Geophysical Union, 79: 197, 200-201.
66. Burns, D.A., Lawrence, G.B., and Murdoch, P.S., 1998, Catskill streams still susceptible to acid rain, Northeastern Geology and Environmental Sciences, 20: 294-298.
66. Burns, D.A., Lawrence, G.B., and Murdoch, P.S., 1998, Catskill streams still susceptible to acid rain, Northeastern Geology and Environmental Sciences, 20: 294-298.
Driscoll, C.T., Cirmo, C.P., Fahey, T.J., Blette, V.L., Bukaveckas, P.A., Burns, D.A., Gubala, C.P., Leopold, D.J., Newton, R.M., Raynal, D.J., Schofield, C.L., Yavitt, J.B., and Porcella, D.B., 1996, The experimental watershed liming study: Comparison of lake and watershed neutralization strategies, Biogeochemistry, 32: 143-174.
McDonnell, J.J., Freer, J., Hooper, R., Kendall, C., Burns, D., Beven, K., and Peters, J., 1996, New method developed for studying flow on hillslopes, Eos, Transactions, American Geophysical Union, 77: 465 and 472.
Clair, T.C., Burns, D.A., Perez, I.R., Blais, J., and Percy, K., 2011, Ecosystems, in: Technical Challenges of Multipollutant Air Quality Management, Hidy, G., Brook, J.R., Demerjian, K.L., Molina, L.T., Pennell, W.T., and Scheffe, R. (eds.), Springer, Dordrecht, Netherlands, Ch. 6, p. 139-229.
Nguyen, L., Rutherford, K., and Burns, D., 1999, Denitrification and nitrate removal in two contrasting riparian wetlands, in: Proceedings of the 20th New Zealand Land Treatment Collective Technical Session, M. Tomer, M Robinson, and G Gielen (eds.), New Plymouth, New Zealand, p. 127-131.
Kendall, C., Silva, S.R., Chang, C.C.Y., Burns, D.A.., Campbell, D.H., and Shanley, J.B., 1996, Use of the d18O and d15N of nitrate to determine sources of nitrate in early spring runoff in forested catchments, in: Isotopes in Water Resources Management, Proceedings of the Symposium on Isotopes in Water Resources Management, March 20-24, 1995, Volume 1, IAEA-SM-336/29, International Atomic Energy Agency, Vienna, Austria, p. 167-176.
Kendall, C., Campbell, D.H., Burns, D.A., Shanley, J.B., Silva, S.R., Chang, C.C.Y., 1995, Tracing sources of nitrate in snowmelt runoff using the oxygen and nitrogen isotopic compositions of nitrate, in: Biogeochemistry of Seasonally Snow-Covered Catchments, K.A. Tonnessen, M.W. Williams, M. Trantner, M. (eds.), International Association of Hydrological Sciences Proceedings, July 3-14, 1995, Boulder, CO, I.A.H.S. Publication 228, Wallingford, U.K., p. 339-347.
Hendrey, G.R., Galloway, J.N., Norton, S.A., Schofield, C.L., Burns, D.A., and Shaffer, P.W., 1980, Sensitivity of the eastern United States to acid precipitation impacts on surface waters, in: Drablos, D., and Tollan, A. (eds.), Ecological Impact of Acid Precipitation, SNSF Proceedings, Oslo, p. 216-217.
Allen, G., Burns, D.A., Negra, C., and Thurston, G.D., 2009, Indicator measurements for assessing the impacts of anthropogenic air pollutants on human health and ecosystems, EM: The Magazine for Environmental Managers, Oct. 2009, p. 20-25, Air and Waste Management Association, Pittsburgh, PA.
Burns, D.A., 2005, What do hydrologists mean when they use the term flushing? Hydrological Processes, 19: 1325-1327.
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Filter Total Items: 17
Science and Products
Filter Total Items: 119
Target loads of atmospheric sulfur and nitrogen deposition for protection of acid sensitive aquatic resources in the Adirondack Mountains, New York
The dynamic watershed acid-base chemistry model of acidification of groundwater in catchments (MAGIC) was used to calculate target loads (TLs) of atmospheric sulfur and nitrogen deposition expected to be protective of aquatic health in lakes in the Adirondack ecoregion of New York. The TLs were calculated for two future dates (2050 and 2100) and three levels of protection against lake acidificatio
Authors
T.J. Sullivan, B.J. Cosby, C. T. Driscoll, T.C. McDonnell, A.T. Herlihy, Douglas A. Burns
TOPMODEL simulations of streamflow and depth to water table in Fishing Brook Watershed, New York, 2007-09
TOPMODEL, a physically based, variable-source area rainfall-runoff model, was used to simulate streamflow and depth to water table for the period January 2007-September 2009 in the 65.6 square kilometers of Fishing Brook Watershed in northern New York. The Fishing Brook Watershed is located in the headwaters of the Hudson River and is predominantly forested with a humid, cool continental climate.
Authors
Elizabeth A. Nystrom, Douglas A. Burns
Setting limits: Using air pollution thresholds to protect and restore US ecosystems
More than four decades of research provide unequivocal evidence that sulfur, nitrogen, and mercury pollution have altered, and will continue to alter, our nation's lands and waters. The emission and deposition of air pollutants harm native plants and animals, degrade water quality, affect forest productivity, and are damaging to human health. Many air quality policies limit emissions at the source
Authors
Mark E. Fenn, Kathleen F. Lambert, Tamara F. Blett, Douglas A. Burns, Linda H. Pardo, Gary M. Lovett, Richard A. Haeuber, David C. Evers, Charles T. Driscoll, Dean S. Jeffries
Spatial patterns of mercury in macroinvertebrates and fishes from streams of contrasting forested landscapes in the eastern United States
Controls on mercury bioaccumulation in lotic ecosystems are not well understood. During 2007–2009, we studied mercury and stable isotope spatial patterns of macroinvertebrates and fishes from two medium-sized (
Authors
Karen Riva-Murray, Lia C. Chasar, Paul M. Bradley, Douglas A. Burns, Mark E. Brigham, Martyn J. Smith, Thomas A. Abrahamsen
Spatial and seasonal variability of dissolved methylmercury in two stream basins in the Eastern United States
We assessed methylmercury (MeHg) concentrations across multiple ecological scales in the Edisto (South Carolina) and Upper Hudson (New York) River basins. Out-of-channel wetland/floodplain environments were primary sources of filtered MeHg (F-MeHg) to the stream habitat in both systems. Shallow, open-water areas in both basins exhibited low F-MeHg concentrations and decreasing F-MeHg mass flux. Do
Authors
Paul M. Bradley, Douglas A. Burns, Karen Riva-Murray, Mark E. Brigham, Daniel T. Button, Lia C. Chasar, Mark Marvin-DiPasquale, Mark A. Lowery, Celeste A. Journey
Effects of acid deposition on ecosystems: Advances in the state of the science
Chapter 2 focused on the environmental results of the ARP, presenting data from national monitoring networks on SO2 and NOx emissions, air quality, atmospheric deposition, surface water chemistry, and visibility. This chapter expands on this information by examining the most recent research into how ecosystems respond to acid deposition, especially the processes that control the recovery of ecosys
Authors
Douglas A. Burns, Mark E. Fenn, Jill Baron
Hydrological mobilization of mercury and dissolved organic carbon in a snow-dominated, forested watershed: Conceptualization and modeling
The mobilization of mercury and dissolved organic carbon (DOC) during snowmelt often accounts for a major fraction of the annual loads. We studied the role of hydrological connectivity of riparian wetlands and upland/wetland transition zones to surface waters on the mobilization of Hg and DOC in Fishing Brook, a headwater of the Adirondack Mountains, New York. Stream water total mercury (THg) conc
Authors
J. Schelker, Douglas A. Burns, M. Weiler, H. Laudon
The relation of harvesting intensity to changes in soil, soil water, and stream chemistry in a northern hardwood forest, Catskill Mountains, USA
Previous studies have shown that clearcutting of northern hardwood forests mobilizes base cations, inorganic monomeric aluminum (Alim), and nitrate (NO3--N) from soils to surface waters, but the effects of partial harvests on NO3--N have been less frequently studied. In this study we describe the effects of a series of partial harvests of varying proportions of basal area removal (22%, 28% and 68%
Authors
Jason Siemion, Douglas A. Burns, Peter S. Murdoch, Rene H. Germain
National Acid Precipitation Assessment Program Report to Congress: An integrated assessment
Acid deposition, more commonly known as acid rain, occurs when emissions of sulfur dioxide (SO2) and nitrogen oxides (NOx) react in the atmosphere with water, oxygen, and oxidants to form various acidic compounds. Prevailing winds transport the acidic compounds hundreds of miles, often across state and national borders. These acidic compounds then fall to earth in either a wet form (rain, snow, an
Authors
Douglas A. Burns, Mark E. Fenn, Jill Baron, Jason A. Lynch, Bernard J. Cosby
Environmental settings of streams sampled for mercury in New York and South Carolina, 2005-09
This report summarizes the environmental settings of streams in New York and South Carolina, where the U.S. Geological Survey completed detailed investigations during 2005-09 into factors contributing to mercury bioaccumulation in top-predator fish and other stream organisms. Descriptions of location, land use/land cover, climate, precipitation, atmospheric deposition, hydrology, water temperature
Authors
Barbara C. Scudder Eikenberry, Karen Riva-Murray, Martyn J. Smith, Paul M. Bradley, Daniel T. Button, Jimmy M. Clark, Douglas A. Burns, Celeste A. Journey
Setting limits: Using air pollution thresholds to protect and restore U.S. ecosystems
More than four decades of research provide unequivocal evidence that sulfur, nitrogen, and mercury pollution have altered, and will continue to alter, our nation's lands and waters. The emission and deposition of air pollutants harm native plants and animals, degrade water quality, affect forest productivity, and are damaging to human health. Many air quality policies limit emissions at the source
Authors
M.E. Fenn, K.F. Lambert, T.F. Blett, Douglas A. Burns, L.H. Pardo, Gary M. Lovett, R. A. Haeuber, D.C. Evers, C. T. Driscoll, D.S. Jeffries
Total mercury, methylmercury, and selected elements in soils of the Fishing Brook watershed, Hamilton County, New York, and the McTier Creek watershed, Aiken County, South Carolina, 2008
Mercury is an element of on-going concern for human and aquatic health. Mercury sequestered in upland and wetland soils represents a source that may contribute to mercury contamination in sensitive ecosystems. An improved understanding of mercury cycling in stream ecosystems requires identification and quantification of mercury speciation and transport dynamics in upland and wetland soils within a
Authors
Laurel G. Woodruff, William F. Cannon, Christopher D. Knightes, Francis H. Chapelle, Paul M. Bradley, Douglas A. Burns, Mark E. Brigham, Mark A. Lowery
Non-USGS Publications**
Harpold, A.A., Burns, D.A., Walter, T., Shaw, S.B., and Steenhuis, T.S., 2010, Relating hydrogeomorphologic properties to stream buffering chemistry in the Neversink River Watershed, New York State, USA, Hydrological Processes, 24: 3759-3771.
Vidon, P., Allan, C., Burns, D., Duval, T., Gurwick, N., Inamdar, S., Lowrance, R., Okay, J., Scott, D., Sebestyen, S., 2010, Hot spots and hot moments in riparian zones: Potential for improved water quality management, Journal of the American Water Resources Association, 46: 278-298.
Kerr, J.G., Eimers, M.C., Creed, I.F., Adams, M.B., Beall, F., Burns, D., Campbell, J.L., Christopher, S.F., Clair, T.A., Couchesne, F., Duchense, L., Fernandez, I., Houle, D., Jeffries, D.S., Likens, G.E., Mitchell, M.J., Shanley, J., Yao, H., 2012, The effect of seasonal drying on sulphate dynamics in streams across southeastern Canada and the northeastern USA, Biogeochemistry, 111: 393-409.
Burns, D.A., Blett, T., Haeuber, R., Pardo, L., 2008, Critical loads as a policy tool for protecting ecosystems from the effects of air pollutants, Frontiers of Ecology and the Environment, 6: 156-159.
Elliott, E.M., Kendall, C., Boyer, E.W., Burns, D.A., Wankel, S.D., Bain, D.J., Harlin, K., Butler, T.J., Carlton, R., 2007, An isotopic tracer of stationary source NOx emissions across the midwestern and northeastern United States, Environmental Science and Technology, 41: 7661-7667.
Burns, D.A., Plummer, L.N., McDonnell, J.J., Busenberg, E., Casile, G.C., Kendall, C., Hooper, R.P., Freer, J.E., Peters, N.E., Beven, K., and Schlosser, P., 2003, The geochemical evolution of groundwater in a forested Piedmont catchment, Ground Water, 41: 913-925.
Burns, D.A., and Nguyen, L., 2002, Nitrate movement and removal along a shallow groundwater flow path in a riparian wetland within a sheep-grazed pastoral catchment: results of a tracer study, New Zealand Journal of Marine and Freshwater Research, 36: 371-385.
Vitvar, T., Burns, D.A., Lawrence, G.B., McDonnell, J.J., and Wolock, D.M., 2002, Estimation of groundwater residence times in watersheds from the recession of the runoff-hydrograph: method and application in the Neversink watershed, Catskill Mountains, New York, Hydrological Processes, 16: 1871-1877.
Burns, D.A., Lawrence, G.B., and Murdoch, P.S., 1998, Catskill streams still susceptible to acid rain, Eos, Transactions, American Geophysical Union, 79: 197, 200-201.
66. Burns, D.A., Lawrence, G.B., and Murdoch, P.S., 1998, Catskill streams still susceptible to acid rain, Northeastern Geology and Environmental Sciences, 20: 294-298.
66. Burns, D.A., Lawrence, G.B., and Murdoch, P.S., 1998, Catskill streams still susceptible to acid rain, Northeastern Geology and Environmental Sciences, 20: 294-298.
Driscoll, C.T., Cirmo, C.P., Fahey, T.J., Blette, V.L., Bukaveckas, P.A., Burns, D.A., Gubala, C.P., Leopold, D.J., Newton, R.M., Raynal, D.J., Schofield, C.L., Yavitt, J.B., and Porcella, D.B., 1996, The experimental watershed liming study: Comparison of lake and watershed neutralization strategies, Biogeochemistry, 32: 143-174.
McDonnell, J.J., Freer, J., Hooper, R., Kendall, C., Burns, D., Beven, K., and Peters, J., 1996, New method developed for studying flow on hillslopes, Eos, Transactions, American Geophysical Union, 77: 465 and 472.
Clair, T.C., Burns, D.A., Perez, I.R., Blais, J., and Percy, K., 2011, Ecosystems, in: Technical Challenges of Multipollutant Air Quality Management, Hidy, G., Brook, J.R., Demerjian, K.L., Molina, L.T., Pennell, W.T., and Scheffe, R. (eds.), Springer, Dordrecht, Netherlands, Ch. 6, p. 139-229.
Nguyen, L., Rutherford, K., and Burns, D., 1999, Denitrification and nitrate removal in two contrasting riparian wetlands, in: Proceedings of the 20th New Zealand Land Treatment Collective Technical Session, M. Tomer, M Robinson, and G Gielen (eds.), New Plymouth, New Zealand, p. 127-131.
Kendall, C., Silva, S.R., Chang, C.C.Y., Burns, D.A.., Campbell, D.H., and Shanley, J.B., 1996, Use of the d18O and d15N of nitrate to determine sources of nitrate in early spring runoff in forested catchments, in: Isotopes in Water Resources Management, Proceedings of the Symposium on Isotopes in Water Resources Management, March 20-24, 1995, Volume 1, IAEA-SM-336/29, International Atomic Energy Agency, Vienna, Austria, p. 167-176.
Kendall, C., Campbell, D.H., Burns, D.A., Shanley, J.B., Silva, S.R., Chang, C.C.Y., 1995, Tracing sources of nitrate in snowmelt runoff using the oxygen and nitrogen isotopic compositions of nitrate, in: Biogeochemistry of Seasonally Snow-Covered Catchments, K.A. Tonnessen, M.W. Williams, M. Trantner, M. (eds.), International Association of Hydrological Sciences Proceedings, July 3-14, 1995, Boulder, CO, I.A.H.S. Publication 228, Wallingford, U.K., p. 339-347.
Hendrey, G.R., Galloway, J.N., Norton, S.A., Schofield, C.L., Burns, D.A., and Shaffer, P.W., 1980, Sensitivity of the eastern United States to acid precipitation impacts on surface waters, in: Drablos, D., and Tollan, A. (eds.), Ecological Impact of Acid Precipitation, SNSF Proceedings, Oslo, p. 216-217.
Allen, G., Burns, D.A., Negra, C., and Thurston, G.D., 2009, Indicator measurements for assessing the impacts of anthropogenic air pollutants on human health and ecosystems, EM: The Magazine for Environmental Managers, Oct. 2009, p. 20-25, Air and Waste Management Association, Pittsburgh, PA.
Burns, D.A., 2005, What do hydrologists mean when they use the term flushing? Hydrological Processes, 19: 1325-1327.
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Filter Total Items: 17