TY - JOUR
T1 - iSAW
T2 - Integrating Structure, Actors, and Water to study socio-hydro-ecological systems
AU - Hale, Rebecca L.
AU - Armstrong, Andrea
AU - Baker, Michelle A.
AU - Bedingfield, Sean
AU - Betts, David
AU - Buahin, Caleb
AU - Buchert, Martin
AU - Crowl, Todd
AU - Dupont, R. Ryan
AU - Ehleringer, James R.
AU - Endter-Wada, Joanna
AU - Flint, Courtney
AU - Grant, Jacqualine
AU - Hinners, Sarah
AU - Horsburgh, Jeffery S.
AU - Jackson-Smith, Douglas
AU - Jones, Amber S.
AU - Licon, Carlos
AU - Null, Sarah E.
AU - Odame, Augustina
AU - Pataki, Diane E.
AU - Rosenberg, David
AU - Runburg, Madlyn
AU - Stoker, Philip
AU - Strong, Courtenay
N1 - Publisher Copyright:
© 2015 The Authors.
PY - 2015/3/1
Y1 - 2015/3/1
N2 - Urbanization, climate, and ecosystem change represent major challenges for managing water resources. Although water systems are complex, a need exists for a generalized representation of these systems to identify important components and linkages to guide scientific inquiry and aid water management. We developed an integrated Structure-Actor-Water framework (iSAW) to facilitate the understanding of and transitions to sustainable water systems. Our goal was to produce an interdisciplinary framework for water resources research that could address management challenges across scales (e.g., plot to region) and domains (e.g., water supply and quality, transitioning, and urban landscapes). The framework was designed to be generalizable across all human-environment systems, yet with sufficient detail and flexibility to be customized to specific cases. iSAW includes three major components: structure (natural, built, and social), actors (individual and organizational), and water (quality and quantity). Key linkages among these components include: (1) ecological/hydrologic processes, (2) ecosystem/geomorphic feedbacks, (3) planning, design, and policy, (4) perceptions, information, and experience, (5) resource access and risk, and (6) operational water use and management. We illustrate the flexibility and utility of the iSAW framework by applying it to two research and management problems: understanding urban water supply and demand in a changing climate and expanding use of green storm water infrastructure in a semi-arid environment. The applications demonstrate that a generalized conceptual model can identify important components and linkages in complex and diverse water systems and facilitate communication about those systems among researchers from diverse disciplines.
AB - Urbanization, climate, and ecosystem change represent major challenges for managing water resources. Although water systems are complex, a need exists for a generalized representation of these systems to identify important components and linkages to guide scientific inquiry and aid water management. We developed an integrated Structure-Actor-Water framework (iSAW) to facilitate the understanding of and transitions to sustainable water systems. Our goal was to produce an interdisciplinary framework for water resources research that could address management challenges across scales (e.g., plot to region) and domains (e.g., water supply and quality, transitioning, and urban landscapes). The framework was designed to be generalizable across all human-environment systems, yet with sufficient detail and flexibility to be customized to specific cases. iSAW includes three major components: structure (natural, built, and social), actors (individual and organizational), and water (quality and quantity). Key linkages among these components include: (1) ecological/hydrologic processes, (2) ecosystem/geomorphic feedbacks, (3) planning, design, and policy, (4) perceptions, information, and experience, (5) resource access and risk, and (6) operational water use and management. We illustrate the flexibility and utility of the iSAW framework by applying it to two research and management problems: understanding urban water supply and demand in a changing climate and expanding use of green storm water infrastructure in a semi-arid environment. The applications demonstrate that a generalized conceptual model can identify important components and linkages in complex and diverse water systems and facilitate communication about those systems among researchers from diverse disciplines.
KW - framework
KW - human-water system
KW - sociohydrology
UR - http://www.scopus.com/inward/record.url?scp=85000434632&partnerID=8YFLogxK
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U2 - 10.1002/2014EF000295
DO - 10.1002/2014EF000295
M3 - Article
AN - SCOPUS:85000434632
SN - 2328-4277
VL - 3
SP - 110
EP - 132
JO - Earth's Future
JF - Earth's Future
IS - 3
ER -