The Fate of Stationary Tools for Environmental Flow Determination in a Context of Climate Change

Environmental flows (eflows) refer to the amount of water required to sustain aquatic ecosystems. In its formal definition, three flow characteristics need to be minimally maintained: quantity, timing and quality. This overview paper highlights the challenges of some of the current methods used for eflow determination in the context of an evolving climate. As hydrological methods remain popular, they are first analyzed by describing some of the potential caveats associated with their usage when flow time series are non-stationarity. The timing of low-flow events will likely change within a season but will also likely shift in seasonality in some regions. Flow quality is a multi-faceted concept. It is proposed that a first simple step to partly incorporate flow quality in future analyses is to include the water temperature as a covariate. Finally, holistic approaches are also critically revisited, and simple modifications to the Ecological Limits of Flow Alteration (ELOHA) framework are proposed.

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Environmental Flows Legislation and Regulations in Foreign Countries and the Enlightenment to China

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.295-298.2181 ◽

2013 ◽

Vol 295-298 ◽

pp. 2181-2186

Author(s):

Chang Chun Chen ◽

La Chun Wang ◽

Xue Zhang Cao ◽

Jie Song

Keyword(s):

Water Demand ◽

Aquatic Ecosystems ◽

Environmental Flows ◽

Environmental Flow ◽

International Agreement ◽

The Enlightenment ◽

Foreign Countries ◽

The World ◽

Key Factor ◽

Legislative Proposals

Environmental flow is a key factor to protect river ecological system, however, there is no international agreement concerned with environmental flows exclusively so far. This paper demonstrated the importance and urgency of environment water demand in the world and presented summary and analysis of environmental flows legislation and regulations. Europe and other countries have been investigated and compared systematically. At last, specialized legislative proposals were provided for protection of aquatic ecosystems and their environment in China.

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Accounting for environmental flow requirements in global water assessments

Hydrology and Earth System Sciences ◽

10.5194/hess-18-5041-2014 ◽

2014 ◽

Vol 18 (12) ◽

pp. 5041-5059 ◽

Cited By ~ 132

Author(s):

A. V. Pastor ◽

F. Ludwig ◽

H. Biemans ◽

H. Hoff ◽

P. Kabat

Keyword(s):

Flow Regime ◽

Environmental Flows ◽

Environmental Flow ◽

Ecological Condition ◽

Freshwater Ecosystems ◽

Low Flow ◽

Human Needs ◽

High Flows ◽

The Mean ◽

Global Vegetation

Abstract. As the water requirement for food production and other human needs grows, quantification of environmental flow requirements (EFRs) is necessary to assess the amount of water needed to sustain freshwater ecosystems. EFRs are the result of the quantification of water necessary to sustain the riverine ecosystem, which is calculated from the mean of an environmental flow (EF) method. In this study, five EF methods for calculating EFRs were compared with 11 case studies of locally assessed EFRs. We used three existing methods (Smakhtin, Tennant, and Tessmann) and two newly developed methods (the variable monthly flow method (VMF) and the Q90_Q50 method). All methods were compared globally and validated at local scales while mimicking the natural flow regime. The VMF and the Tessmann methods use algorithms to classify the flow regime into high, intermediate, and low-flow months and they take into account intra-annual variability by allocating EFRs with a percentage of mean monthly flow (MMF). The Q90_Q50 method allocates annual flow quantiles (Q90 and Q50) depending on the flow season. The results showed that, on average, 37% of annual discharge was required to sustain environmental flow requirement. More water is needed for environmental flows during low-flow periods (46–71% of average low-flows) compared to high-flow periods (17–45% of average high-flows). Environmental flow requirements estimates from the Tennant, Q90_Q50, and Smakhtin methods were higher than the locally calculated EFRs for river systems with relatively stable flows and were lower than the locally calculated EFRs for rivers with variable flows. The VMF and Tessmann methods showed the highest correlation with the locally calculated EFRs (R2=0.91). The main difference between the Tessmann and VMF methods is that the Tessmann method allocates all water to EFRs in low-flow periods while the VMF method allocates 60% of the flow in low-flow periods. Thus, other water sectors such as irrigation can withdraw up to 40% of the flow during the low-flow season and freshwater ecosystems can still be kept in reasonable ecological condition. The global applicability of the five methods was tested using the global vegetation and the Lund-Potsdam-Jena managed land (LPJmL) hydrological model. The calculated global annual EFRs for fair ecological conditions represent between 25 and 46% of mean annual flow (MAF). Variable flow regimes, such as the Nile, have lower EFRs (ranging from 12 to 48% of MAF) than stable tropical regimes such as the Amazon (which has EFRs ranging from 30 to 67% of MAF).

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Environmental flow assessment in the context of climate change: a case study in Southern Quebec (Canada)

Journal of Water and Climate Change ◽

10.2166/wcc.2021.254 ◽

2021 ◽

Author(s):

Laureline Berthot ◽

André St-Hilaire ◽

Daniel Caissie ◽

Nassir El-Jabi ◽

Judith Kirby ◽

...

Keyword(s):

Climate Change ◽

Environmental Flows ◽

Environmental Flow ◽

Low Flow ◽

Physical Habitat ◽

Climate Change Scenarios ◽

Management Tools ◽

Water Abstraction ◽

The Impact

Abstract Through a case study in Southern Quebec (Canada), the assessment of environmental flows in light of the effects of climate change is investigated. Currently, the 7Q2 flow metric (7-day average flow with a 2-year return period) is used for water abstraction management. Several flow metrics were calculated using flow time series simulated by a deterministic hydrological model (HYDROTEL) and climate change scenarios as inputs. Results were compared within homogeneous low flow regions defined using ascendant hierarchical clustering, for the 1990, 2020 and 2050 horizons and annual, summer and winter periods. The impact of each flow metric on the potential availability of physical habitat was analyzed using the wetted perimeter as a proxy. Results indicated that: (1) the increasing non-stationarity of simulated flow data sets over time will complicate the use of frequency analysis to calculate the 7Q2 flow metric; (2) summer low flow values are expected to be lower than winter low flows; and (3) flow-duration curve metrics like the LQ50 (median discharge value of the month with the lowest flow) may become relevant environmental flow metrics by 2050. Results question current water abstraction management tools and permit to anticipate future local and regional issues during low flow periods.

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Evaluation of environmental flow requirements using eco-hydrologic–hydraulic methods in perennial rivers

Water Science & Technology ◽

10.2166/wst.2015.200 ◽

2015 ◽

Vol 72 (3) ◽

pp. 354-363 ◽

Cited By ~ 18

Author(s):

Reza Abdi ◽

Mehdi Yasi

Keyword(s):

Environmental Flows ◽

Environmental Flow ◽

Low Flow ◽

Flow Duration Curve ◽

North West ◽

Flow Duration ◽

Key Species ◽

Habitat Simulation ◽

Range Of Variability Approach ◽

Ecological Methods

The assessment of environmental flows in rivers is of vital importance for preserving riverine ecosystem processes. This paper addresses the evaluation of environmental flow requirements in three reaches along a typical perennial river (the Zab transboundary river, in north-west Iran), using different hydraulic, hydrological and ecological methods. The main objective of this study came from the construction of three dams and inter-basin transfer of water from the Zab River to the Urmia Lake. Eight hydrological methods (i.e. Tennant, Tessman, flow duration curve analysis, range of variability approach, Smakhtin, flow duration curve shifting, desktop reserve and 7Q2&10 (7-day low flow with a 2- and 10-year return period)); two hydraulic methods (slope value and maximum curvature); and two habitat simulation methods (hydraulic–ecologic, and Q Equation based on water quality indices) were used. Ecological needs of the riverine key species (mainly Barbus capito fish), river geometries, natural flow regime and the environmental status of river management were the main indices for determining the minimum flow requirements. The results indicate that the order of 35%, 17% and 18% of the mean annual flow are to be maintained for the upper, middle and downstream river reaches, respectively. The allocated monthly flow rates in the three Dams steering program are not sufficient to preserve the Zab River life.

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Environmental Flow Estimation of Brunei River Based on Climate Change

Environment and Urbanization Asia ◽

10.1177/09754253211047201 ◽

2021 ◽

pp. 097542532110472

Author(s):

Shahriar Shams ◽

Md Sumon Reza ◽

Abul Kalam Azad ◽

Rozeana Binti Hj. Md. Juani ◽

Mohammad Abul Fazal

Keyword(s):

Climate Change ◽

Environmental Flows ◽

Threshold Value ◽

Environmental Flow ◽

Planning System ◽

Low Flow ◽

Potential Growth ◽

Flow Estimation ◽

Brunei Darussalam ◽

Main Challenge

The concept of environmental flows and its application and enforcement is a main challenge in several developing countries. The services and benefits derived from the ecosystem are indispensable for sustaining the livelihood of people particularly living in coastal areas. Decision-makers often ignore ecosystems when referring to water allocation, as the supporters of ecosystems are less vocal as compared to other stakeholders. This study focuses on establishing guidelines for maintaining the minimum amount of flow known as environmental flow of Brunei River in Brunei Darussalam for the sustainability of its rich ecosystem. In this study, the flow of the river was simulated based on land use, climate change, and potential growth of industries using a Water Evaluation and Planning System as a computing tool. The study finds that the months of March and June (1.48 and 3.92 m3/s) are more vulnerable to low flow. It recommends a threshold value of 2.7 m3/s for the environmental flow of Brunei River essential to preserve its rich and diversified ecosystem.

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Environmental Flows

Environmental Science ◽

10.1093/obo/9780199363445-0116 ◽

2019 ◽

Author(s):

Ryan Morrison ◽

Erin Bray

Keyword(s):

River Flow ◽

Environmental Flows ◽

Spatial Scales ◽

Flow Characteristics ◽

River System ◽

Environmental Flow ◽

Flow Dynamics ◽

Management Policy ◽

River Health ◽

Riverine Ecosystems

Environmental flows are commonly defined as the river-flow characteristics necessary to maintain the integrity of riverine ecosystems. The concept of environmental flows has evolved over the past half-century, beginning with the development of minimum instream flows necessary to protect a single fish species to current frameworks for holistically including all aspects of river health that depend on natural flow regimes. This also includes the interaction of terrestrial environments with riverine ecosystems during large flooding events. The challenges associated with defining and implementing environmental flows are numerous, and they sometimes lack data necessary to define flow-ecology relationships, appropriate temporal and spatial scales for environmental flow applications, and incorporate environmental flows into water management policy. Given these challenges, researchers and practitioners have made incredible advances in better understanding the relationships between river health and flow dynamics, including the links among flow, sediment, temperature, and human activities. In addition, computational advances have allowed researchers to more accurately model flow-habitat relationships at fine scales, providing a more complete understanding of the connection between flow and habitat needs for riverine species. All these advances benefit from holistic frameworks that guide environmental flow development and applications while considering the needs of other water uses in a river system. This article presents relevant studies regarding approaches for developing environmental flows, relationships between riverine ecology and flow dynamics, and policy frameworks and tools useful for implementing environmental flows in practice.

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“E = mc2” of Environmental Flows: A Conceptual Framework for Establishing a Fish-Biological Foundation for a Regionally Applicable Environmental Low-Flow Formula

Water ◽

10.3390/w10111501 ◽

2018 ◽

Vol 10 (11) ◽

pp. 1501 ◽

Cited By ~ 5

Author(s):

Piotr Parasiewicz ◽

Paweł Prus ◽

Katarzyna Suska ◽

Paweł Marcinkowski

Keyword(s):

Environmental Flows ◽

Regional Scale ◽

Biological Significance ◽

Aquatic Organisms ◽

Pilot Project ◽

Standard Setting ◽

Environmental Flow ◽

Low Flow ◽

Fish Community Structure ◽

Body Type

Determination of environmental flows at the regional scale has been complicated by the fine-scale variability of the needs of aquatic organisms. Therefore, most regional methods are based on observation of hydrological patterns and lack evidence of connection to biological responses. In contrast, biologically sound methods are too detailed and resource-consuming for applications on larger scales. The purpose of this pilot project was to develop an approach that would breach this gap and provide biologically sound rules for environmental flow (eflow) estimation for the region of Poland. The concept was developed using seven river sites, which represent the four of six fish-ecological freshwater body types common in Poland. Each of these types was distinguished based on a specific fish community structure, composed of habitat-use guilds. The environmental significance of the flows for these communities was established with help of the habitat simulation model MesoHABSIM computed for each of the seven sites. The established seasonal environmental flow thresholds were standardized to the watershed area and assigned to the corresponding water body type. With these obtained environmental flow coefficients, a standard-setting formula was created, which is compatible with existing standard-setting approaches while maintaining biological significance. The proposed approach is a first attempt to use habitat suitability models to justify a desktop formula for the regional scale eflow criteria.

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Environmental flow envelopes: quantifying global, ecosystem–threatening streamflow alterations

10.5194/hess-2021-260 ◽

2021 ◽

Author(s):

Vili Virkki ◽

Elina Alanärä ◽

Miina Porkka ◽

Lauri Ahopelto ◽

Tom Gleeson ◽

...

Keyword(s):

Climate Change ◽

Upper Bound ◽

Environmental Flows ◽

Environmental Flow ◽

Fine Tuning ◽

Low Flow ◽

Practical Applications ◽

Riverine Ecosystems ◽

Basin Scale ◽

The World

Abstract. Human actions and climate change have drastically altered river flows across the world, resulting in adverse effects on riverine ecosystems. Environmental flows (EFs) have emerged as a prominent tool for safeguarding riverine ecosystems. However, at the global scale, the assessment of EFs is associated with significant uncertainty. Here, we present a novel method to determine EFs by Environmental Flow Envelopes (EFE), which is an envelope of variability bounded by discharge limits within which riverine ecosystems are not seriously compromised. The EFE is defined globally in approximately 4,400 sub–basins at monthly time resolution, considering also the methodological uncertainties related with global EF studies. In addition to a lower bound of discharge, the EFE introduces an upper bound of discharge, identifying areas where streamflow has increased substantially. Further, instead of only showing whether EFs are violated, as commonly done, we quantify, for the first time, the frequency, severity, and trends of EFE violations, which can be considered as potential threats to riverine ecosystems. We use pre–industrial (1801–1860) quasi-natural discharge and a suite of hydrological EFR methods and global hydrological models to estimate EFE, applying data from the ISIMIP 2b ensemble. We then compare the EFEs to recent past (1976–2005) discharge to assess the violations of the EFE. We found that the EFE violations most commonly manifest themselves by insufficient streamflow during the low flow season, with less violations during intermediate flow season, and only few violations during high flow season. These violations are widespread: discharge in half of the sub–basins of the world has violated the EFE during more than 5 % of the months between 1976 and 2005. The trends in EFE violations have mainly been increasing during the past decades and will likely remain problematic with projected increases in anthropogenic water use and hydroclimatic changes. Indications of excessive streamflow through EFE upper bound violations are relatively scarce and spatially distributed, although signs of increasing trends can be identified and potentially attributed to climate change. While the EFE provides a quick and globally robust way of determining environmental flow allocations at the sub–basin scale, local fine–tuning is necessary for practical applications and further research on the coupling between quantitative discharge and riverine ecosystem responses is required.

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