Your search keyword '"John C. Hammond"' showing total 3 results

1. Pervasive changes in stream intermittency across the United States

Author

Margaret Shanafield, Michelle H. Busch, Daniel C. Allen, Amy J. Burgin, Julian D. Olden, Meryl C. Mims, C. Nathan Jones, K. E. Kaiser, Adam S. Ward, Stephanie K. Kampf, Margaret A. Zimmer, Kate S. Boersma, Joanna R. Blaszczak, Walter K. Dodds, John C. Hammond, George H. Allen, Thibault Datry, Corey A. Krabbenhoft, Ryan M. Burrows, Sarah E. Godsey, A. N. Price, Katie H. Costigan, Samuel C. Zipper, Kansas Geological Survey, University of Kansas [Lawrence] (KU), U.S Geological Survey, Flinders University [Adelaide, Australia], University of California [Santa Cruz] (UCSC), University of California, Riverly (Riverly), Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), University of South Alabama, Boise State University, IDAHO STATE UNIVERSITY POCATELLO USA, Partenaires IRSTEA, Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), University of Melbourne, University of Nevada [Reno], University of Oklahoma (OU), University of San Diego, Indiana University [Bloomington], Indiana University System, University of Louisiana at Lafayette, Partenaires INRAE, Texas A&M University [College Station], University at Buffalo [SUNY] (SUNY Buffalo), State University of New York (SUNY), Kansas State University, Virginia Tech [Blacksburg], School of Aquatic and Fishery Sciences (University of Washington), Colorado State University [Fort Collins] (CSU), and National Science Foundation (NSF) : DEB-1754389

Subjects

non-perennial streams, 010504 meteorology & atmospheric sciences, river, 0207 environmental engineering, Climate change, 02 engineering and technology, STREAMS, 01 natural sciences, law.invention, law, Intermittency, Streamflow, Ecosystem, 020701 environmental engineering, 0105 earth and related environmental sciences, General Environmental Science, Land use, Renewable Energy, Sustainability and the Environment, Ephemeral key, Public Health, Environmental and Occupational Health, land use, 15. Life on land, Arid, 6. Clean water, climate change, Geography, 13. Climate action, [SDE]Environmental Sciences, streamflow, Physical geography, time series, ephemeral

Abstract

Non-perennial streams are widespread, critical to ecosystems and society, and the subject of ongoing policy debate. Prior large-scale research on stream intermittency has been based on long-term averages, generally using annually aggregated data to characterize a highly variable process. As a result, it is not well understood if, how, or why the hydrology of non-perennial streams is changing. Here, we investigate trends and drivers of three intermittency signatures that describe the duration, timing, and dry-down period of stream intermittency across the continental United States (CONUS). Half of gages exhibited a significant trend through time in at least one of the three intermittency signatures, and changes in no-flow duration were most pervasive (41% of gages). Changes in intermittency were substantial for many streams, and 7% of gages exhibited changes in annual no-flow duration exceeding 100 days during the study period. Distinct regional patterns of change were evident, with widespread drying in southern CONUS and wetting in northern CONUS. These patterns are correlated with changes in aridity, though drivers of spatiotemporal variability were diverse across the three intermittency signatures. While the no-flow timing and duration were strongly related to climate, dry-down period was most strongly related to watershed land use and physiography. Our results indicate that non-perennial conditions are increasing in prevalence over much of CONUS and binary classifications of 'perennial' and 'non-perennial' are not an accurate reflection of this change. Water management and policy should reflect the changing nature and diverse drivers of changing intermittency both today and in the future. US National Science FoundationNational Science Foundation (NSF) [DEB-1754389] Published version This manuscript is a product of the Dry Rivers Research Coordination Network, which was supported by funding from the US National Science Foundation (DEB-1754389). Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the US Government. This manuscript was improved by constructive feedback from Kristin Jaeger and three anonymous reviews.

Published

2021

2. Agricultural tile drains increase the susceptibility of streams to longer and more intense streamflow droughts

Author

Seth R Adelsperger, Darren L Ficklin, Scott M Robeson, Margaret A Zimmer, John C Hammond, Damon M Hall, and J P Gannon

Subjects

streamflow drought, agriculture, tile drainage, watershed, climate, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Streamflow droughts are receiving increased attention worldwide due to their impact on the environment and economy. One region of concern is the Midwestern United States, whose agricultural productivity depends on subsurface pipes known as tile drains to improve trafficability and soil conditions for crop growth. Tile drains accomplish this by rapidly transporting surplus soil moisture and shallow groundwater from fields, resulting in reduced watershed storage. However, no work has previously examined the connection between tile drainage and streamflow drought. Here, we pose the question: does the extent of watershed-level tile drainage lead to an increased susceptibly and magnitude of streamflow droughts? To answer this, we use daily streamflow data for 122 watersheds throughout the Midwestern United States to quantify streamflow drought duration, frequency, and intensity. Using spatial multiple regression models, we find that agricultural tile drainage generates statistically significant ( p < 0.05) increases in streamflow drought duration and intensity while significantly reducing drought frequency. The magnitude of the effect of tile drainage on streamflow drought characteristics is similar to that of water table depth and precipitation seasonality, both of which are known to influence streamflow droughts. Furthermore, projected changes in regional precipitation characteristics will likely drive the installation of additional tile drainage. We find that for each 10% increase in tile-drained watershed area, streamflow drought duration and intensity increase by 0.03 d and 12%, respectively, while frequency decreases by 0.10 events/year. Such increases in tile drainage may lead to more severe streamflow droughts and have a detrimental effect on the socio-environmental usage of streams throughout the Midwest.

Published

2024

3. Pervasive changes in stream intermittency across the United States

Author

Samuel C Zipper, John C Hammond, Margaret Shanafield, Margaret Zimmer, Thibault Datry, C Nathan Jones, Kendra E Kaiser, Sarah E Godsey, Ryan M Burrows, Joanna R Blaszczak, Michelle H Busch, Adam N Price, Kate S Boersma, Adam S Ward, Katie Costigan, George H Allen, Corey A Krabbenhoft, Walter K Dodds, Meryl C Mims, Julian D Olden, Stephanie K Kampf, Amy J Burgin, and Daniel C Allen

Subjects

non-perennial streams, climate change, land use, river, streamflow, ephemeral, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Non-perennial streams are widespread, critical to ecosystems and society, and the subject of ongoing policy debate. Prior large-scale research on stream intermittency has been based on long-term averages, generally using annually aggregated data to characterize a highly variable process. As a result, it is not well understood if, how, or why the hydrology of non-perennial streams is changing. Here, we investigate trends and drivers of three intermittency signatures that describe the duration, timing, and dry-down period of stream intermittency across the continental United States (CONUS). Half of gages exhibited a significant trend through time in at least one of the three intermittency signatures, and changes in no-flow duration were most pervasive (41% of gages). Changes in intermittency were substantial for many streams, and 7% of gages exhibited changes in annual no-flow duration exceeding 100 days during the study period. Distinct regional patterns of change were evident, with widespread drying in southern CONUS and wetting in northern CONUS. These patterns are correlated with changes in aridity, though drivers of spatiotemporal variability were diverse across the three intermittency signatures. While the no-flow timing and duration were strongly related to climate, dry-down period was most strongly related to watershed land use and physiography. Our results indicate that non-perennial conditions are increasing in prevalence over much of CONUS and binary classifications of ‘perennial’ and ‘non-perennial’ are not an accurate reflection of this change. Water management and policy should reflect the changing nature and diverse drivers of changing intermittency both today and in the future.

Published

2021