Effective modeling for Integrated Water Resource Management: A guide to contextual practices by phases and steps and future opportunities

Badham, Jennifer; Elsawah, Sondoss; Guillaume, Joseph H. A.; Hamilton, Serena H.; Hunt, Randall J.; Jakeman, Anthony J.; Pierce, Suzanne A.; Snow, Val; Babbar-Sebens, Meghna; Fu, Baihua; Gober, Patricia; Hill, Mary C.; Iwanaga, Takuya; Loucks, Daniel P.; Merritt, Wendy; Peckham, S. D.; Richmond, Amy K.; Zare, Fateme; Ames, Daniel P.; Bammer, Gabriele

doi:10.1016/j.envsoft.2019.02.013

Cited by 86 publications

(57 citation statements)

References 116 publications

(121 reference statements)

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“…The need for numerical ecological models continues growing as scientists are asked to forecast the effects of management actions, anticipate future conditions and understand ecosystems without historical analogs (Carpenter and Turner, 2017). Ecological models are also increasingly integrated across disciplines, modeling traditions, and epistemologies (Voinov and Fishwick, 2019), particularly for multi-objective problems like ecosystem restoration, habitat conservation, and integrated water resource management (Addison et al, 2013;Langsdale et al, 2013;Badham et al, 2019). As models become more ubiquitous, the need for clear, transparent communication strategies are essential for distilling model complexity and achieving consensus from diverse audiences and stakeholders that are involved with the decision-making process.…”

Section: Discussionmentioning

confidence: 99%

Unpacking the Black Box: Demystifying Ecological Models Through Interactive Workshops and Hands-On Learning

Herman

McKay

Altman

et al. 2019

Front. Environ. Sci.

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Section: Discussionmentioning

confidence: 99%

Unpacking the Black Box: Demystifying Ecological Models Through Interactive Workshops and Hands-On Learning

Herman

McKay

Altman

et al. 2019

Front. Environ. Sci.

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“…Integrated water resources management (IWRM) is a watershed-focused water management framework. Several core principles underlying IWRM and the planetary boundaries overlap: Both frameworks treat different stores of water as inherently interconnected and include land surface processes in the scope of water management (Badham et al, 2019). Since IWRM is designed to be applied at the watershed scale, the water planetary boundary provides a complementary framework for considering water flows that cross watershed boundaries through pathways including the following:…”

Section: Watershed or Aquifer Management (Single Jurisdiction Or Tranmentioning

confidence: 99%

“…Second, accounting for scientific uncertainty is a longstanding challenge for water management (Badham et al, 2019;Merz et al, 2015;Poff et al, 2016;Varela-Ortega et al, 2011;Wei et al, 2011). Given the complexities inherent in Earth System dynamics, numerous aleatoric and epistemic uncertainties are embedded in the planetary boundaries framework.…”

Section: 1029/2019ef001377mentioning

confidence: 99%

Integrating the Water Planetary Boundary With Water Management From Local to Global Scales

et al. 2020

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The planetary boundaries framework defines the “safe operating space for humanity” represented by nine global processes that can destabilize the Earth System if perturbed. The water planetary boundary attempts to provide a global limit to anthropogenic water cycle modifications, but it has been challenging to translate and apply it to the regional and local scales at which water problems and management typically occur. We develop a cross‐scale approach by which the water planetary boundary could guide sustainable water management and governance at subglobal contexts defined by physical features (e.g., watershed or aquifer), political borders (e.g., city, nation, or group of nations), or commercial entities (e.g., corporation, trade group, or financial institution). The application of the water planetary boundary at these subglobal contexts occurs via two approaches: (i) calculating fair shares, in which local water cycle modifications are compared to that context's allocation of the global safe operating space, taking into account biophysical, socioeconomic, and ethical considerations; and (ii) defining a local safe operating space, in which interactions between water stores and Earth System components are used to define local boundaries required for sustaining the local water system in stable conditions, which we demonstrate with a case study of the Cienaga Grande de Santa Marta wetlands in Colombia. By harmonizing these two approaches, the water planetary boundary can ensure that water cycle modifications remain within both local and global boundaries and complement existing water management and governance approaches.

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“…In the environmental sector, modelling serves a variety of interrelated purposes, including decision support, scientific discovery, and social learning (Badham et al, 2019;Gober 2018). In the water sector, for example, it supports a range of water management decisions, including infrastructure construction and operations, flood control and drought management, harvesting and storing water above and below ground, maintaining healthy ecosystems, and allocation of water for agriculture, energy production, cities, and environmental uses (Loucks, et al 2005;Mulligan and Ahlfeld 2016;Snow et al, 2016;Sharvelle et al, 2017;Robert et al 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Evaluation of modelling projects helps improve the modelling when conducted within an ongoing model development process such as that described in phases and steps by Badham et al (2019) for integrated water resource management. It enables weaknesses to be identified and resolved and can also allow the experience from one modelling project to improve future modelling.…”

Section: Introductionmentioning

confidence: 99%

A framework for characterising and evaluating the effectiveness of environmental modelling

Hamilton

Guillaume

et al. 2019

Environmental Modelling & Software

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Environmental modelling is transitioning from the traditional paradigm that focuses on the model and its quantitative performance to a more holistic paradigm that recognises successful model-based outcomes are closely tied to undertaking modelling as a social process, not just as a technical procedure. This paper redefines evaluation as a multi-dimensional and multi-perspective concept, and proposes a more complete framework for identifying and measuring the effectiveness of modelling that serves the new paradigm. Under this framework, evaluation considers a broader set of success criteria, and emphasises the importance of contextual factors in determining the relevance and outcome of the criteria. These evaluation criteria are grouped into eight categories: project efficiency, model accessibility, credibility, saliency, legitimacy, satisfaction, application, and impact. Evaluation should be part of an iterative and adaptive process that attempts to improve model-based outcomes and foster pathways to better futures.

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Effective modeling for Integrated Water Resource Management: A guide to contextual practices by phases and steps and future opportunities

Cited by 86 publications

References 116 publications

Unpacking the Black Box: Demystifying Ecological Models Through Interactive Workshops and Hands-On Learning

Unpacking the Black Box: Demystifying Ecological Models Through Interactive Workshops and Hands-On Learning

Integrating the Water Planetary Boundary With Water Management From Local to Global Scales

A framework for characterising and evaluating the effectiveness of environmental modelling

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