TY - JOUR
T1 - Streamflow Depletion Caused by Groundwater Pumping
T2 - Fundamental Research Priorities for Management-Relevant Science
AU - Zipper, Sam
AU - Brookfield, Andrea
AU - Ajami, Hoori
AU - Ayers, Jessica R.
AU - Beightel, Chris
AU - Fienen, Michael N.
AU - Gleeson, Tom
AU - Hammond, John
AU - Hill, Mary
AU - Kendall, Anthony D.
AU - Kerr, Ben
AU - Lapides, Dana
AU - Porter, Misty
AU - Parimalarenganayaki, S.
AU - Rohde, Melissa M.
AU - Wardropper, Chloe
N1 - Publisher Copyright:
© 2024 The Authors. This article has been contributed to by U.S. Government employees and their work is in the public domain in the USA.
PY - 2024/5
Y1 - 2024/5
N2 - Reductions in streamflow caused by groundwater pumping, known as “streamflow depletion,” link the hydrologic process of stream-aquifer interactions to human modifications of the water cycle. Isolating the impacts of groundwater pumping on streamflow is challenging because other climate and human activities concurrently impact streamflow, making it difficult to separate individual drivers of hydrologic change. In addition, there can be lags between when pumping occurs and when streamflow is affected. However, accurate quantification of streamflow depletion is critical to integrated groundwater and surface water management decision making. Here, we highlight research priorities to help advance fundamental hydrologic science and better serve the decision-making process. Key priorities include (a) linking streamflow depletion to decision-relevant outcomes such as ecosystem function and water users to align with partner needs; (b) enhancing partner trust and applicability of streamflow depletion methods through benchmarking and coupled model development; and (c) improving links between streamflow depletion quantification and decision-making processes. Catalyzing research efforts around the common goal of enhancing our streamflow depletion decision-support capabilities will require disciplinary advances within the water science community and a commitment to transdisciplinary collaboration with diverse water-connected disciplines, professions, governments, organizations, and communities.
AB - Reductions in streamflow caused by groundwater pumping, known as “streamflow depletion,” link the hydrologic process of stream-aquifer interactions to human modifications of the water cycle. Isolating the impacts of groundwater pumping on streamflow is challenging because other climate and human activities concurrently impact streamflow, making it difficult to separate individual drivers of hydrologic change. In addition, there can be lags between when pumping occurs and when streamflow is affected. However, accurate quantification of streamflow depletion is critical to integrated groundwater and surface water management decision making. Here, we highlight research priorities to help advance fundamental hydrologic science and better serve the decision-making process. Key priorities include (a) linking streamflow depletion to decision-relevant outcomes such as ecosystem function and water users to align with partner needs; (b) enhancing partner trust and applicability of streamflow depletion methods through benchmarking and coupled model development; and (c) improving links between streamflow depletion quantification and decision-making processes. Catalyzing research efforts around the common goal of enhancing our streamflow depletion decision-support capabilities will require disciplinary advances within the water science community and a commitment to transdisciplinary collaboration with diverse water-connected disciplines, professions, governments, organizations, and communities.
KW - groundwater withdrawals
KW - research priorities
KW - stream-aquifer interactions
KW - streamflow depletion
KW - transdisciplinary science
KW - water resources management
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U2 - 10.1029/2023WR035727
DO - 10.1029/2023WR035727
M3 - Comment/debate
AN - SCOPUS:85192191691
SN - 0043-1397
VL - 60
JO - Water Resources Research
JF - Water Resources Research
IS - 5
M1 - e2023WR035727
ER -