States and rates: Complementary approaches to developing flow‐ecology relationships

Wheeler, Kit; Wenger, Seth J.; Freeman, Mary C.

doi:10.1111/fwb.13001

Cited by 40 publications

(65 citation statements)

References 53 publications

(75 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Wheeler et al. () report that measurement of ecological states, including their repeated measurement over time, comprise 72% of reviewed approaches for characterising flow–ecology relationships. Against this trend, some have argued that ecological processes, rather than habitat limitation per se, are a more appropriate focus for e‐flows (e.g.…”

Section: Emerging Challenges For E‐flows Sciencementioning

confidence: 99%

“…For example, recruitment failure by insects (Kennedy et al., ) or riparian trees (Lytle & Merritt, ; Rood et al., ) does not manifest in species abundances for many months, and shifts in community structure under flow regulation (Mims & Olden, ) is a relatively slow process that can be measured across many sites simultaneously using monitoring data. The repeated measurement of snapshot state variables over time constitutes a kind of temporally varying ecological properties and is a predominant form of flow–ecology relationship reported in the literature (Wheeler et al., ).…”

Section: Emerging Challenges For E‐flows Sciencementioning

confidence: 99%

See 1 more Smart Citation

Beyond the natural flow regime? Broadening the hydro‐ecological foundation to meet environmental flows challenges in a non‐stationary world

2017

View full text Add to dashboard Cite

The natural flow regime concept has contributed significantly to environmental flows (e‐flows) science and applications over the last 20 years. Natural flow regimes reflect long‐term, historical patterns of flow variability that have shaped riverine species’ adaptations and continue to shape community and ecosystem structure and function. This scientific perspective, however, carries with it important assumptions about climatic and ecological stationarity in terms of “reference” conditions that provide a basis for comparing success or outcomes of e‐flow interventions. Non‐stationarity in climate and other environmental conditions (temperature, sediment, nutrients) and in ecological features (non‐native species spread) presents important challenges for environmental flows science. Reliance on the assumption of restoration to reference conditions for either hydrologic or ecological conditions is no longer tenable, and an expanded e‐flows science foundation is needed to meet several challenges facing future e‐flows implementations. Currently recognised limitations of e‐flows science contribute to the emergence of research frontiers that need further development. These are (1) shifting from static, regime‐based flow metrics to dynamic, time‐varying flow characterisations; (2) expanding the ecological metrics (and space–time scales) used in e‐flows from primary reliance on ecosystem states to include process (population) rates and species traits; (3) incorporating other “non‐flow” environmental features (e.g. temperature, sediment) to guide prioritisation of e‐flows applications with a likelihood of success; and (4) broadening the ecological foundation of e‐flows to incorporate more ecological theory that will contribute to a more predictive science. The natural flow regime perspective of managing for historical variability will remain important to understand ecological response to hydrologic alterations and to inform e‐flows management. However, under shifting hydro‐climatic and ecological conditions, a new imperative of managing for resilience is emerging, that is, identifying and prescribing e‐flows to sustain robust, persistent and socially valued ecological characteristics in a flexible and adaptive management framework.

show abstract

Section: Emerging Challenges For E‐flows Sciencementioning

confidence: 99%

Section: Emerging Challenges For E‐flows Sciencementioning

confidence: 99%

Beyond the natural flow regime? Broadening the hydro‐ecological foundation to meet environmental flows challenges in a non‐stationary world

2017

View full text Add to dashboard Cite

show abstract

“…However, their literature review shows that many studies involve a third approach, “repeated states,” characterised by “temporally repeated measurements of ecological state responses.” Repeated‐state responses expressed as rate responses can generate predictions of biotic response to specific flow sequences over time, although they do not reveal the actual mechanisms underlying the dynamics of ecological change. While the authors recognise the strengths and limitations of all these approaches, they argue that “rates approaches have been underused to date and could facilitate substantial progress” in mechanistic understanding of flow–ecological relationships (Wheeler et al., ).…”

Section: Developments In Environmental Flows Science and Modellingmentioning

confidence: 99%

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

et al. 2018

View full text Add to dashboard Cite

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.

show abstract

“…For freshwater populations, predictions that extreme hydrologic events, such as floods and droughts, will increase (Ingram et al 2013, National Academies of Sciences 2016) are of particular concern. We have a limited understanding of how aquatic populations will respond to hydrologic changes (Walters 2016, Wheeler et al 2017. We have a limited understanding of how aquatic populations will respond to hydrologic changes (Walters 2016, Wheeler et al 2017.…”

Section: Introductionmentioning

confidence: 99%

Seasonal streamflow extremes are key drivers of Brook Trout young‐of‐the‐year abundance

2018

View full text Add to dashboard Cite

To manage ecosystems in the context of climate change, we need to understand the relationship between extreme events and population dynamics. Floods and droughts are projected to occur more frequently, but how aquatic species will respond to these extreme events remains uncertain. Based on counts of Brook Trout (Salvelinus fontinalis) collected over 28 yr at 115 sites in Shenandoah National Park, we developed mixed-effects models to (1) assess how well extreme streamflow, as compared to mean flows and total precipitation, can explain young-of-the-year (YOY) abundance, (2) identify potential nonlinear relationships between seasonal environmental covariates and abundance using nonlinear generalized additive mixed models, and (3) explore likely impacts of expected future weather and streamflow conditions. We found that (1) using covariates of streamflow extremes improved prediction of YOY abundance compared to use of mean seasonal flow values or precipitation as a proxy, (2) warmer maximum daily spring temperatures were associated with increased YOY abundance up to about 1.5 standard deviations, above which abundance declined, and (3) a strong negative effect of extreme winter streamflow, unlikely to be offset by possibly positive effects from other seasons, is expected to have a detrimental impact on Brook Trout populations given predicted increases in winter precipitation. Because YOY abundance is a strong determinant of population dynamics for these short-lived species, extreme events will have the potential to exert a strong influence on population persistence of Brook Trout in a changing climate. Management actions that maximize resiliency of populations in response to extreme events, such as restoration of habitat connectivity, should be prioritized to buffer negative impacts.

show abstract

States and rates: Complementary approaches to developing flow‐ecology relationships

Cited by 40 publications

References 53 publications

Beyond the natural flow regime? Broadening the hydro‐ecological foundation to meet environmental flows challenges in a non‐stationary world

Beyond the natural flow regime? Broadening the hydro‐ecological foundation to meet environmental flows challenges in a non‐stationary world

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

Seasonal streamflow extremes are key drivers of Brook Trout young‐of‐the‐year abundance

Contact Info

Product

Resources

About