TY - JOUR
T1 - Virtual Hydrological Laboratories
T2 - Developing the Next Generation of Conceptual Models to Support Decision Making Under Change
AU - Thyer, Mark
AU - Gupta, Hoshin
AU - Westra, Seth
AU - McInerney, David
AU - Maier, Holger R.
AU - Kavetski, Dmitri
AU - Jakeman, Anthony
AU - Croke, Barry
AU - Simmons, Craig
AU - Partington, Daniel
AU - Shanafield, Margaret
AU - Tague, Christina
N1 - Publisher Copyright:
© 2024. The Authors.
PY - 2024/4
Y1 - 2024/4
N2 - As hydrological systems are pushed outside the envelope of historical experience, the ability of current hydrological models to serve as a basis for credible prediction and decision making is increasingly challenged. Conceptual models are the most common type of surface water hydrological model used for decision support due to reasonable performance in the absence of change, ease of use and computational speed that facilitate scenario, sensitivity and uncertainty analysis. Hence, conceptual models in effect represent the current “shopfront” of hydrological science as seen by practitioners. However, these models have notable limitations in their ability to resolve internal catchment processes and subsequently capture hydrological change. New thinking is needed to confront the challenges faced by the current generation of conceptual models in dealing with a changing environment. We argue the next generation of conceptual models should combine the parsimony of conceptual models with our best available scientific understanding. We propose a strategy to develop such models using multiple hydrological lines of evidence. This strategy includes using appropriately selected physically resolved models as “Virtual Hydrological Laboratories” to test and refine the simpler models' ability to predict future hydrological changes. This approach moves beyond the sole focus on “predictive skill” measured using metrics of historical performance, facilitating the development of the next generation of conceptual models with hydrological fidelity (i.e., models that “get the right answers for the right reasons”). This quest is more than a scientific curiosity; it is expected by policy makers who need to know what to plan for.
AB - As hydrological systems are pushed outside the envelope of historical experience, the ability of current hydrological models to serve as a basis for credible prediction and decision making is increasingly challenged. Conceptual models are the most common type of surface water hydrological model used for decision support due to reasonable performance in the absence of change, ease of use and computational speed that facilitate scenario, sensitivity and uncertainty analysis. Hence, conceptual models in effect represent the current “shopfront” of hydrological science as seen by practitioners. However, these models have notable limitations in their ability to resolve internal catchment processes and subsequently capture hydrological change. New thinking is needed to confront the challenges faced by the current generation of conceptual models in dealing with a changing environment. We argue the next generation of conceptual models should combine the parsimony of conceptual models with our best available scientific understanding. We propose a strategy to develop such models using multiple hydrological lines of evidence. This strategy includes using appropriately selected physically resolved models as “Virtual Hydrological Laboratories” to test and refine the simpler models' ability to predict future hydrological changes. This approach moves beyond the sole focus on “predictive skill” measured using metrics of historical performance, facilitating the development of the next generation of conceptual models with hydrological fidelity (i.e., models that “get the right answers for the right reasons”). This quest is more than a scientific curiosity; it is expected by policy makers who need to know what to plan for.
KW - climate change
KW - conceptual hydrological models
KW - hydrological model development
KW - hydrological non-stationarity
KW - Virtual Hydrological Laboratory
UR - http://www.scopus.com/inward/record.url?scp=85189971250&partnerID=8YFLogxK
U2 - 10.1029/2022WR034234
DO - 10.1029/2022WR034234
M3 - Comment/debate
AN - SCOPUS:85189971250
SN - 0043-1397
VL - 60
JO - Water Resources Research
JF - Water Resources Research
IS - 4
M1 - e2022WR034234
ER -