TY - JOUR
T1 - Efectos de los proyectos de protección en el uso de la tierra y en las cuencas hídricas para una gestión sostenible de las aguas subterráneas en un acuífero fuertemente explotado en Hawai‘i (EEUU)
AU - Bremer, Leah L.
AU - Elshall, Ahmed S.
AU - Wada, Christopher A.
AU - Brewington, Laura
AU - Delevaux, Jade M.S.
AU - El-Kadi, Aly I.
AU - Voss, Clifford I.
AU - Burnett, Kimberly M.
N1 - Funding Information: This research was funded in part by the National Science Foundation EPSCoR Grant No. OIA 1557349. Funding Information: We thank Katie Ersbak (Department of Forestry and Wildlife)?and?Will Weaver (Ko?olau Watershed Partnership) for input on the forest conservation scenarios, and?Leo Asunci?n (Hawai?i State Office of Planning) and the City and County of Honolulu for input into the development scenarios. We also gratefully acknowledge guidance from Gregory Chun from the University of Hawai?i, and Roy Hardy and Lenore Ohye from?the Hawai?i Commission on Water Resource Management. We also thank Uli?i Miyajima, David Wade, and Scott Cloudwatcher, who provided technical assistance with scenario development.?The simulation optimization method was developed with technical support from Delwyn Oki at USGS. The technical support and advanced computing resources from the University of Hawai?i Information Technology Services ? Cyberinfrastructure are gratefully acknowledged, especially David Schanzenback, Ron Merrill and Sean Cleveland. The data and simulation optimization codes developed for this study are available upon contacting the second author.?This is contributed paper #?CP-2021-14 of the Water Resources Research Center at the University of Hawai?i at M?noa. Publisher Copyright: © 2021, The Author(s).
PY - 2021/8
Y1 - 2021/8
N2 - Groundwater sustainability initiatives, including sustainable yield and watershed policy protection policies, are growing globally in response to increasing demand for groundwater, coupled with concerns about the effects of climate and land-cover change on groundwater supply. Improved understanding of the impacts of watershed management on groundwater yields and management costs—particularly in the broader context of climate and land-cover change—is critical to inform these initiatives and facilitate integrated land and water management. This study develops a novel, spatially explicit groundwater hydrologic ecosystem services framework, which combines stakeholder-defined land-cover scenarios, sustainable yield estimation using a groundwater simulation optimization approach, and economic valuation, and applies it in the most heavily utilized aquifer Hawai‘i (USA). Sustainable yield estimates and resulting differences in replacement costs are estimated for six land-cover scenarios (with varying levels of urban development and watershed management) crossed with two water demand scenarios in a context of a dry future climate (Representative Concentration Pathway [RCP] 8.5 mid-century). Land-cover change is found to be an important, though less significant drive of changes in groundwater recharge than climate change. The degree of watershed protection, through preventing the spread of high-water-use, invasive plant species, is projected to be a much stronger land-cover signal than urban development. Specifically, full forest protection increases sustainable yield by 7–11% (30–45 million liters per day) and substantially decreases treatment costs compared with no forest protection. Collectively, this study demonstrates the hydrologic and economic value of watershed protection in a context of a dry future climate, providing insights for integrated land and water policy and management in Hawai‘i and other regions, particularly where species invasions threaten source watersheds.
AB - Groundwater sustainability initiatives, including sustainable yield and watershed policy protection policies, are growing globally in response to increasing demand for groundwater, coupled with concerns about the effects of climate and land-cover change on groundwater supply. Improved understanding of the impacts of watershed management on groundwater yields and management costs—particularly in the broader context of climate and land-cover change—is critical to inform these initiatives and facilitate integrated land and water management. This study develops a novel, spatially explicit groundwater hydrologic ecosystem services framework, which combines stakeholder-defined land-cover scenarios, sustainable yield estimation using a groundwater simulation optimization approach, and economic valuation, and applies it in the most heavily utilized aquifer Hawai‘i (USA). Sustainable yield estimates and resulting differences in replacement costs are estimated for six land-cover scenarios (with varying levels of urban development and watershed management) crossed with two water demand scenarios in a context of a dry future climate (Representative Concentration Pathway [RCP] 8.5 mid-century). Land-cover change is found to be an important, though less significant drive of changes in groundwater recharge than climate change. The degree of watershed protection, through preventing the spread of high-water-use, invasive plant species, is projected to be a much stronger land-cover signal than urban development. Specifically, full forest protection increases sustainable yield by 7–11% (30–45 million liters per day) and substantially decreases treatment costs compared with no forest protection. Collectively, this study demonstrates the hydrologic and economic value of watershed protection in a context of a dry future climate, providing insights for integrated land and water policy and management in Hawai‘i and other regions, particularly where species invasions threaten source watersheds.
KW - Groundwater management
KW - Hydrologic ecosystem services
KW - Invasive species
KW - Sustainable yield
KW - Water supply
KW - Watershed management
UR - http://www.scopus.com/inward/record.url?scp=85104958298&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85104958298&partnerID=8YFLogxK
U2 - 10.1007/s10040-021-02310-6
DO - 10.1007/s10040-021-02310-6
M3 - Article
SN - 1431-2174
VL - 29
SP - 1749
EP - 1765
JO - Hydrogeology Journal
JF - Hydrogeology Journal
IS - 5
ER -