A Metacoupling Framework for Exploring Transboundary Watershed Management

Merz, Leandra; Yang, Di; Hull, Vanessa

doi:10.3390/su12051879

Cited by 11 publications

(5 citation statements)

References 43 publications

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“…The project responds to this demand by applying the coupled human and natural systems (CHANS) framework [1][2][3] to analyze the intersection of localized water issues with climate change. The results underscore the challenges emerging from changing water fortunes globally [4].…”

Section: Introductionmentioning

confidence: 85%

Climate Change and Water Dynamics in Rural Uganda

McKinney

Wright

2021

Sustainability

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The purpose of this case study is to examine the effects of climate change on agricultural life in rural Uganda. Based on primary data, the authors examine major themes related to climate change and disasters as conveyed by individuals in a small agricultural region in Eastern Uganda. Specifically, we focus on the effects of living in constant threat of flooding and landslides. Results show that water is a major source of loss for most people, ranging from crop loss to contaminated water. Findings also point to the chronic nature of dealing with water issues, as opposed to acute. Further, our results indicate that disasters are a great equalizer among affected populations, with only neighbors to depend on in the aftermath.

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Section: Introductionmentioning

confidence: 85%

Climate Change and Water Dynamics in Rural Uganda

McKinney

Wright

2021

Sustainability

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“…The metacoupling framework has been proposed to integrate human and natural interactions within a system (intracoupling), between adjacent systems (pericoupling), and between distant systems (telecoupling) (Figure 3) (Liu, 2017(Liu, , 2018. The framework has already been adopted in a range of studies, regarding watershed management (Merz et al, 2020), the diagnosis of inequity in cultivated land use (Chuai et al, 2021), the food-energy-water-CO 2 nexus in agricultural irrigation (Xu et al, 2020), and the fishery management (Carlson et al, 2020). Furthermore, some studies have already attempted to use the metacoupling framework in ecosystem services (Zhao et al, 2018).…”

Section: From Chans To Metacouplingmentioning

confidence: 99%

Understanding ecosystem services in a metacoupled world

Sun

2023

Transactions in Earth, Environment, and Sustainability

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Driven by intensive globalization and technological development, shifting from place-based research on ecosystem services to an understanding of multiple human and natural interactions within the focal system, as well as between adjacent and distant systems, is becoming an urgent necessity. An integrated framework of metacoupling (socio-economic-environmental interactions within and across borders) is proposed to address this shift. Here, I have demonstrated the utility of the metacoupling framework, which includes intracoupling, pericoupling, and telecoupling, in the assessment of ecosystem services. I have referred to three examples from China (water supply, soybean production and trade, banana planation and displacement). I have also provided regulations and cautions in the application of the metacoupling framework. Strengthening the assessment of ecosystem services with the metacoupling framework can yield important insights toward sustaining ecosystem service provisions, balancing trade, offs, promoting regional and global cooperation, and achieving the United Nation’s Sustainable Development Goals.

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“…This has led to methodological developments to understand and model the dynamics of coupled human-water systems (Du et al, 2020;X. Li et al, 2018;Noël & Cai, 2017;Merz et al, 2020;Sivapalan et al, 2012;Cai et al, 2015). Several studies focus on feedback and interactions among water resource systems and human behavior in relation to floods, droughts, water supply, and groundwater exploitation.…”

Section: Introductionmentioning

confidence: 99%

Quantifying the value of stakeholder elicited information in models of coupled human-water systems

Sunkara,

Singh,

Bhave

2023

Preprint

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Causal loop diagrams (CLDs) based on expert and/or stakeholder inputs inform the quantitative structure of socio-hydrological models (SHMs). However, a systematic exploration of the sensitivity of CLDs and SHMs to different levels of stakeholder inputs is lacking. For a large multi-purpose reservoir in southern India, we explore this sensitivity by developing three CLDs that integrate reservoir water balance, groundwater pumping, and consumer water use patterns. CLD1 is a conventional water balance-based reservoir model, while CLD2 additionally incorporates the reservoir operatorâ\euro™s judgment and groundwater pumping. CLD3 further incorporates the adaptive behavior of water users by adjusting demands in response to long-term (5-year) droughts. The correlation between observed and simulated monthly reservoir storage (2000-2013) for SHM1, SHM2, and SHM3 is 0.57, 0.85, and 0.87, respectively. SHM3 also outperforms SHM1 and SHM2 in simulating the relative use of surface and groundwater for irrigation purposes in the command area of the reservoir. Simulated demand deficits, command area groundwater levels, and minimum environmental flow satisfaction downstream of the reservoir for 1968-2013 using the three models exhibit substantial differences. SHM1 and SHM2 simulate deteriorating groundwater levels under the multi-year drought of 2001-2003 while SHM3 does not due to the consideration of adaptive farmer behavior. Thus, our understanding of water and food security during a multi-year drought can be significantly affected by the level of stakeholder inputs incorporated in the models. We highlight the importance of testing different SHMs structures to better understand human-water interactions under extreme conditions.

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A Metacoupling Framework for Exploring Transboundary Watershed Management

Cited by 11 publications

References 43 publications

Climate Change and Water Dynamics in Rural Uganda

Climate Change and Water Dynamics in Rural Uganda

Understanding ecosystem services in a metacoupled world

Quantifying the value of stakeholder elicited information in models of coupled human-water systems

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