How much groundwater can we pump and protect environmental flows through time? Presumptive standards for conjunctive management of aquifers and rivers

Gleeson, Tom; Richter, Brian

doi:10.1002/rra.3185

Cited by 127 publications

(122 citation statements)

References 68 publications

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“…effluent water returns) hydrological changes. There is a paucity of information on how groundwater abstraction influences riverine ecosystems globally (Gleeson & Richter, ; Poff & Zimmerman, ). Given that groundwater abstraction practices are increasingly and severely depleting subsurface water resources (Gleeson, Wada, Bierkens, & van Beek, ) and substantially reducing river discharges globally (De Graaf et al., ), studies such as this are vital for guiding e‐flow science and sustainable groundwater management operations.…”

Section: Discussionmentioning

confidence: 99%

“…Flow regime variability is widely recognised as a primary factor shaping riverine ecosystems (Ledger & Milner, ; Monk et al., ; Poff, ; Thompson, King, Kingsford, Mac Nally, & Poff, ). However, land use changes (Chadwick et al., ; López‐Moreno et al., ) and water resource management practices have profoundly altered river flow regimes (De Graaf, Van Beek, Wada, & Bierkens, ; Gleeson & Richter, ; Lehner et al., ), significantly threatening the integrity of lotic ecosystems globally (Bunn & Arthington, ; Poff et al., ; Vörösmarty et al., ). For example, groundwater abstraction substantially reduces river discharges worldwide (De Graaf et al., ) and profoundly alters lotic ecosystems (Bradley, Streetly, Farren, Cadman, & Banham, ; Bradley et al., ; Kennen, Riskin, & Charles, ).…”

Section: Introductionmentioning

confidence: 99%

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Habitat‐specific invertebrate responses to hydrological variability, anthropogenic flow alterations, and hydraulic conditions

et al. 2019

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Quantifying ecological responses to river flow regimes is a key scientific approach underpinning many environmental flow (e‐flow) strategies. Incorporating habitat‐scale influences (e.g. substrate composition and organic matter cover) within e‐flow frameworks has the potential to provide a broader understanding of the causal mechanisms shaping instream communities, which may be used to guide river management strategies. In this study, we examined invertebrate communities inhabiting three distinct habitat groups (HGs—defined by coarse substrates, fine sediments, and the fine‐leaved macrophyte Ranunculus sp.) across four rivers (each comprising two study sites) within a single catchment. We tested the structural and functional responses of communities inhabiting different HGs to three sets of flow‐related characteristics: (1) antecedent hydrological (discharge—m3/s) variability; (2) antecedent anthropogenic flow alterations (percentage of discharge added to or removed from the river by human activity); and (3) proximal hydraulic conditions (characterised by the Froude number). The former two were derived from groundwater model daily time series in the year prior to the collection of each invertebrate sample, while the latter was collected at the point of sampling. While significant effects of hydrological and anthropogenic flow alteration indices were detected, Froude number exerted the greatest statistical influence on invertebrate communities. This highlights that habitat‐scale hydraulic conditions to which biota are exposed at the time of sampling are a key influence on the structure and function of invertebrate communities. Mixed‐effect models testing invertebrate community responses to flow‐related characteristics, most notably Froude number, improved when a HG interaction term was incorporated. This highlights that different mineralogical and organic habitat patches mediate ecological responses to hydraulic conditions. This can be attributed to HGs supporting distinct taxonomic and functional compositions and/or providing unique ecological functions (e.g. flow refuges), which alter how instream communities respond to hydraulic conditions. While the individual importance of both flow and small‐scale habitat effects on instream biota has been widely reported, this study provides rare evidence on how their interactive effects have a significant influence on riverine ecosystems. These findings suggest that river management strategies and e‐flow frameworks should not only aim to create a mosaic of riverine habitats that support ecosystem functioning, but also consider the management of local hydraulic conditions within habitat patches to support specific taxonomic and functional compositions.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Habitat‐specific invertebrate responses to hydrological variability, anthropogenic flow alterations, and hydraulic conditions

et al. 2019

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“…These include aquifer and cave systems; "ecosystems fully or partly dependent on the surface expression of groundwater including wetlands, lakes, seeps, springs, river baseflow, coastal areas, estuaries, and marine ecosystems"; and "ecosystems dependent on subsurface presence of groundwater (via the capillary fringe), including terrestrial vegetation that depends on groundwater fully or on an irregular basis to meet water requirements." Environmental flow management must address the lotic, lentic and groundwater phases of all freshwater-dependent aquatic ecosystems, including their riparian and basin surroundings, to sustain their ecological integrity, ecosystem services and societal values (Bunn, 2016;Datry et al, 2017;Gleeson and Richter, 2017;Horne et al, 2017c;Kennen et al, 2018). To achieve a more integrated approach that considers the water requirements of inter-connected surface and GDEs will be one of the next grand challenges of environmental flows science and management.…”

Section: Definition Of Environmental Flowsmentioning

confidence: 99%

The Brisbane Declaration and Global Action Agenda on Environmental Flows (2018)

Arthington

Bhaduri

Bunn

et al. 2018

Front. Environ. Sci.

336

225

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“…More attention, improved assessment methods, modelling and ecological response monitoring are needed to integrate groundwater‐dependent ecosystems into environmental flows assessment and management (e.g. Arthington, ; Eamus & Froend, ; Gleeson & Richter, ; Richardson et al., ). Quantify/predict the interaction between hydrology, sedimentary processes, geomorphology, hydraulics, temperature and ecological variables: Improved understanding of these interactions will help parse out the degree to which flow variability and management are the main drivers of ecological change, and how each affects physical elements (e.g. sediment, temperature) that in turn shape habitat, biological communities and ecosystem processes (e.g.…”

Section: Scientific Challenges and Areas For Further Explorationmentioning

confidence: 99%

“…This section outlines themes where advances in management tools and approaches could be accomplished: Include additional waterbody types in water allocation strategies: Relatively, little work has been carried out on the water requirements of lentic waterbodies, wetlands, groundwater‐dependent ecosystems and coastal systems, even though these may be particularly impacted by hydrologic alteration (e.g. Arthington, ; Gleeson & Richter, ). Expanding the scope of environmental watering beyond flowing waters has generated debate around terminology.…”

Section: Advancing the Management Of Environmental Watermentioning

confidence: 99%

Recent advances in environmental flows science and water management—Innovation in the Anthropocene

et al. 2018

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The implementation of environmental flow regimes offers a promising means to protect and restore riverine, wetland and estuarine ecosystems, their critical environmental services and cultural/societal values. This Special Issue expands the scope of environmental flows and water science in theory and practice, offering 20 papers from academics, agency researchers and non‐governmental organisations, each with fresh perspectives on the science and management of environmental water allocations. Contributions confront the grand challenge for environmental flows and water management in the Anthropocene—the urgent need for innovations that will help to sustain the innate resilience of social–ecological systems under dynamic and uncertain environmental and societal futures. Basin‐scale and regional assessments of flow requirements mark a necessary advance in environmental water science in the face of rapid changes in water‐resource management activities worldwide (e.g. increases in dams, diversions, retention and reuse). Techniques for regional‐scale hydrological and ecohydrological modelling support ecological risk assessment and identification of priority flow management and river restoration actions. Changing flood–drought cycles, long‐term climatic shifts and associated effects on hydrological, thermal and water quality regimes add enormous uncertainty to the prediction of future ecological outcomes, regardless of environmental water allocations. An improved capacity to predict the trajectories of ecological change in rivers degraded by legacies of past impact interacting with current conditions and future climate change is essential. Otherwise, we risk unrealistic expectations from restoration of river and estuarine flow regimes. A more robust, dynamic and predictive approach to environmental water science is emerging. It encourages the measurement of process rates (e.g. birth rate, colonisation rate) and species traits (e.g. physiological requirements, morphological adaptations) as well as ecosystem states (e.g. species richness, assemblage structure), as the variables representing ecological responses to flow variability and environmental water allocations. Another necessary development is the incorporation of other environmental variables such as water temperature and sedimentary processes in flow–ecological response models. Based on contributions to this Special Issue, several recent compilations and the wider literature, we identify six major scientific challenges for further exploration, and seven themes for advancing the management of environmental water. We see the emerging frontier of environmental flows and water science as urgent and challenging, with numerous opportunities for reinvigorated science and methodological innovation in the expanding enterprise of environmental water linked to ecological sustainability and social well‐being.

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How much groundwater can we pump and protect environmental flows through time? Presumptive standards for conjunctive management of aquifers and rivers

Cited by 127 publications

References 68 publications

Habitat‐specific invertebrate responses to hydrological variability, anthropogenic flow alterations, and hydraulic conditions

Habitat‐specific invertebrate responses to hydrological variability, anthropogenic flow alterations, and hydraulic conditions

The Brisbane Declaration and Global Action Agenda on Environmental Flows (2018)

Recent advances in environmental flows science and water management—Innovation in the Anthropocene

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