Poor correlation between large-scale environmental flow violations and freshwater biodiversity: implications for water resource management and the freshwater planetary boundary

Mohan, Chinchu; Gleeson, Tom; Famiglietti, J. S.; Virkki, Vili; Kummu, Matti; Porkka, Miina; Wang‐Erlandsson, Lan; Huggins, Xander; Gerten, Dieter; Jähnig, Sonja C.

doi:10.5194/hess-26-6247-2022

Cited by 4 publications

(6 citation statements)

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“…Another critical issue is that few studies have tried to link the water PB across different scales; specifically, the following two issues are not well resolved: (a) the connections among local water PBs, as most studies used local data without considering its connectivity with other regions, and (b) the impact of local water-PB transgressions at large scales, as no previous studies have investigated how local water-PB transgressions could trigger a water-PB transgression at a larger scale or at the global scale. However, Mohan et al (2022) found poor relationship between EWF-biodiversity at large scales, even though it is well established at small scales, implying the need for a holistic approach for water PB research across different scales. Recently, Zipper et al (2020) proposed a novel framework to address the challenge associated with mismatched control variables between the global and local scales, but the above two issues are still not well-resolved in a quantitative way.…”

Section: Assessments At Different Scalesmentioning

confidence: 89%

“…The seasonal variation of water flow rate (e.g., flood flow) and the mismatch between the water supply and human water demand can result in a portion of unused water resources. Second, the control‐response relationship between freshwater biodiversity and EWF has not been well represented in the determination of EWF (Mohan et al., 2022), which further challenges the quantification of water PB based on EWF. Third, there is a large uncertainty in runoff estimates derived through multiple global hydrological models (GHMs), which would propagate into the estimation of EWF.…”

Section: Discussionmentioning

confidence: 99%

“…However, Mohan et al. (2022) found poor relationship between EWF‐biodiversity at large scales, even though it is well established at small scales, implying the need for a holistic approach for water PB research across different scales. Recently, Zipper et al.…”

Section: Discussionmentioning

confidence: 99%

“…Third, there is a large uncertainty in runoff estimates derived through multiple global hydrological models (GHMs), which would propagate into the estimation of EWF. Finally, the fixed coefficients derived through the VMF method in water PB expressions are major source of uncertainties, as flow patterns among river basins and relationship between EWF-biodiversity are highly spatially heterogeneous (Mohan et al, 2022). Moreover, considering only a mini- 2022), deviations in the whole freshwater cycle beyond the pre-industrial variability range were assessed based on the blue-green water division, indicating a likely water PB transgression (Porkka et al, 2022).…”

Section: Quantification Methods For Thresholdsmentioning

confidence: 99%

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Review of Quantitative Applications of the Concept of the Water Planetary Boundary at Different Spatial Scales

Han

Leng

2023

Water Resources Research

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With the advent of the Anthropocene (Lewis & Maslin, 2015), many critical Earth-system processes have been significantly impacted, thus placing the system at great risk of reaching a dangerous level (Steffen et al., 2018). The "planetary boundary" (PB) concept was proposed (Rockstrom et al., 2009a(Rockstrom et al., , 2009b to define a safe operating space for humanity without destabilizing critical planetary processes, with the Holocene baseline corresponding to the optimal planetary state (O'Neill et al., 2018). Specifically, nine PBs have been defined, and climate change and biodiversity integrity have been identified as two core PBs due to the significant impacts of these factors on the Earth system (Steffen et al., 2018). By emphasizing the urgency of taking appropriate actions to defend the Earth against the risks of crossing the "tipping point," PB research has had a considerable impact on global policy-making (Galaz et al., 2012).As an essential part of the PB framework, the water PB provides a global limitation to human manipulation of the water cycle (Rockstrom et al., 2009a). The initial determination of the water PB was made by Rockstrom et al. (2009a), who adopted a blue-water (i.e., water in aquifers, lakes, and dams) use magnitude of 4,000 (4,000-6,000) km 3 /yr as the water PB. A subsequent revision was made by Gerten et al. (2013), who proposed a blue-water use magnitude of 2,800 (1,100-4,500) km 3 /yr as the water PB. In the latest version of the PB framework (Steffen et al., 2015), proposed a two-level water PB, including a global-scale PB and a basin-scale PB. Recently, Gleeson, proposed a series of subboundaries to better examine the role of water-cycle modifications in Earth system resilience. Zipper et al. (2020) further explored how to integrate the water PB with water management from the local to global scales by harmonizing the quantification approaches of fair shares (top-down) and local safe operating spaces (bottom-up). In addition to the blue water-based PB, Wang-Erlandsson et al. (2022) attempted to quantify the water PB from the green water (i.e., terrestrial precipitation, evaporation, and soil moisture) perspective, and indicated a transgression of the green water PB.

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Section: Assessments At Different Scalesmentioning

confidence: 89%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Quantification Methods For Thresholdsmentioning

confidence: 99%

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Review of Quantitative Applications of the Concept of the Water Planetary Boundary at Different Spatial Scales

Han

Leng

2023

Water Resources Research

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“…Impacts of streamflow depletion on aquatic ecosystems may be through direct changes in streamflow or indirectly through changes in water quality or temperature caused by depletion, as in the case of salmonids which are highly dependent on cool groundwater inflows (Larsen & Woelfle-Erskine, 2018) and are a major driver of policy and management decisions in many settings (Lackey, 1999). While a variety of approaches to estimate environmental flow needs for aquatic ecosystems have been developed and proposed, these are not well-correlated with freshwater biodiversity (Mohan et al, 2022), suggesting that more information beyond just changes in water quantity is needed to link streamflow depletion to adverse ecological outcomes (Lapides et al, 2022;Yarnell et al, 2020). While recent studies have identified low-flow signatures as most sensitive to streamflow depletion across diverse hydrologic regions (Lapides et al, 2023), links between hydrologic change and ecological outcomes have predominantly been local (Liu et al, 2020;Perkin et al, 2017).…”

Section: Decision Support Steps: Identify Decision Need(s) and Decisi...mentioning

confidence: 99%

Streamflow Depletion Caused by Groundwater Pumping: Fundamental Research Priorities for Management‐Relevant Science

Zipper,

Brookfield,

Ajami

et al. 2024

Water Resources Research

Self Cite

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Reductions in streamflow caused by groundwater pumping, known as “streamflow depletion,” link the hydrologic process of stream‐aquifer interactions to human modifications of the water cycle. Isolating the impacts of groundwater pumping on streamflow is challenging because other climate and human activities concurrently impact streamflow, making it difficult to separate individual drivers of hydrologic change. In addition, there can be lags between when pumping occurs and when streamflow is affected. However, accurate quantification of streamflow depletion is critical to integrated groundwater and surface water management decision making. Here, we highlight research priorities to help advance fundamental hydrologic science and better serve the decision‐making process. Key priorities include (a) linking streamflow depletion to decision‐relevant outcomes such as ecosystem function and water users to align with partner needs; (b) enhancing partner trust and applicability of streamflow depletion methods through benchmarking and coupled model development; and (c) improving links between streamflow depletion quantification and decision‐making processes. Catalyzing research efforts around the common goal of enhancing our streamflow depletion decision‐support capabilities will require disciplinary advances within the water science community and a commitment to transdisciplinary collaboration with diverse water‐connected disciplines, professions, governments, organizations, and communities.

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Environmental Flow Increases The Riparian Vegetation Diversity And Community Similarity

Guo,

Xue,

Wang

et al. 2024

Wetlands

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Poor correlation between large-scale environmental flow violations and freshwater biodiversity: implications for water resource management and the freshwater planetary boundary

Cited by 4 publications

References 82 publications

Review of Quantitative Applications of the Concept of the Water Planetary Boundary at Different Spatial Scales

Review of Quantitative Applications of the Concept of the Water Planetary Boundary at Different Spatial Scales

Streamflow Depletion Caused by Groundwater Pumping: Fundamental Research Priorities for Management‐Relevant Science

Environmental Flow Increases The Riparian Vegetation Diversity And Community Similarity

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