Ecosystem‐based environmental flow assessment in a Greek regulated river with the use of 2D hydrodynamic habitat modelling

Theodoropoulos, Christos; Skoulikidis, Nikolaos Th.; Rutschmann, Peter; Stamou, Anastasios I.

doi:10.1002/rra.3284

Cited by 35 publications

(25 citation statements)

References 37 publications

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“…In the absence of well‐established fish communities in the Oinoi stream (possibly due to the extreme long‐term hydrological alteration caused by the presence of the upstream reservoir), we used benthic macroinvertebrates as our target aquatic community, which have been found to be more widely distributed (Monk et al, ) and are commonly used in such cases elsewhere (Waddle & Holmquist, ). Their habitat preferences were acquired from the benthos‐GR dataset (Theodoropoulos, Skoulikidis, et al, ), which consists of 380 microhabitat observations sampled in Greek streams and rivers of similar environmental and hydraulic properties. The benthos‐GR dataset calculates habitat suitability ( K ) using benthic community metrics (no.…”

Section: Methodsmentioning

confidence: 99%

“…The dataset was used to train and cross‐validate a fuzzy Bayesian algorithm, described in detail in Theodoropoulos, Skoulikidis, et al () and implemented using the Habfuzz software (Theodoropoulos, Skoulikidis, & Stamou, ). In the fuzzy Bayesian algorithm, the numerical inputs of V and D are converted to overlapping, five‐class, trapezoidal‐shaped membership functions (called fuzzy sets).…”

Section: Methodsmentioning

confidence: 99%

“…Following the approach of Theodoropoulos, Skoulikidis, et al (), the optimal ecosystem‐based eflow scenario was selected on the basis of the combination of the following indicators–variables: Overall suitability index (OSI):

OSI = \sum_{i = 1}^{w} K_{i} .

Average OSI (nOSI):

nOSI = \frac{OSI}{w},

where K i (from 0 to 1) denotes the habitat suitability and w denotes the total no. of wetted nodes in the computational grid at each Q scenario.…”

Section: Methodsmentioning

confidence: 99%

“…Environmental flows (eflows) describe the quantity, timing, and quality of the water flows required to sustain freshwater and estuarine ecosystems and the human livelihoods and well‐being that depend on these ecosystems (Brisbane Declaration, ). During 40 years of research, more than 200 methods for assessing eflows emerged worldwide (Tharme, ) and have been recently categorized in three groups depending on the type of data they use to calculate eflows: (a) hydrological methods, which assess eflows based on long‐term historical hydrological information (Richter, Baumgartner, Powell, & Braun, ; Tennant, ); (b) habitat simulation (also known as hydraulic/hydrodynamic habitat modelling) methods, which develop eflow scenarios based on the interaction between habitat suitability–availability and the distribution of aquatic biota (Koutrakis et al, ; Leitner, Hauer, & Graf, ; Theodoropoulos, Skoulikidis, et al, ; Vezza, Muñoz‐Mas, Martínez‐Capel, & Mouton, ); and (c) holistic methods, which combine hydrological and hydroecological/habitat information to define eflows for multiple biotic elements of the aquatic ecosystem (Water Framework Directive Common Implementation Strategy [WFD CIS] Guidance Document No. 31, ), including fish, benthic macroinvertebrates, and aquatic and riparian vegetation (King, Tharme, & De Villiers, ; Poff et al, ; Solans & Jalón, ).…”

Section: Introductionmentioning

confidence: 99%

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Comparing environmental flow scenarios from hydrological methods, legislation guidelines, and hydrodynamic habitat models downstream of the Marathon Dam (Attica, Greece)

et al. 2018

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In their effort to balance anthropogenic water demand and ecosystem conservation within a sustainable water resources management framework, water managers and stakeholders need sound scientific guidance. In this study, we applied a two-dimensional hydrodynamic habitat model using benthic macroinvertebrates as the target aquatic community and carried out an environmental flow (eflow) assessment downstream of the Marathon Reservoir (Attica, Central Greece). Hydrology-based eflow scenarios were additionally developed over an 11-year period, and the lowest acceptable ecosystem-based eflow was compared with the hydrology-based eflow predictions. We found that the hydrological methods tend to underestimate the eflows required to ensure functional aquatic ecosystems. The results showed that (a) the different hydrological methods developed highly variable eflow scenarios, ranging from 0.0006 to 0.18 m 3 /s, (b) the ecosystem-based eflow was up to 183% higher than the hydrology-based ones and 26% to 465% higher than those defined by the national legislation, and (c) the probability of agreement between hydrological and ecological predictions was 12.5%, as only one out of the eight hydrology-based scenarios coincided with the ecosystem-based eflows. We conclude that hydrological methods should be used with caution in the absence of ecological information. Their use as stand-alone tools seems problematic and bears a high risk of producing inappropriate eflow scenarios. Integrative frameworks combining hydrological-ecological methods could be useful to provide information on what is ecologically acceptable and hydrologically socially feasible, but because the two methods comprise structurally different, noninteracting concepts, they are inherently insufficient to increase the confidence of predicting and selecting eflows.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

OSI = \sum_{i = 1}^{w} K_{i} .

Average OSI (nOSI):

nOSI = \frac{OSI}{w},

where K i (from 0 to 1) denotes the habitat suitability and w denotes the total no. of wetted nodes in the computational grid at each Q scenario.…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Comparing environmental flow scenarios from hydrological methods, legislation guidelines, and hydrodynamic habitat models downstream of the Marathon Dam (Attica, Greece)

et al. 2018

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“…The habitat preference datasets are then used as training data in hydraulic habitat models, that is, the reference data which will be used by the model to predict the habitat suitability (K) in samples/microhabitats with known V, D, and S values and unknown K. Currently, there are various alternatives available for the development of habitat suitability criteria, reflecting the aforementioned challenging effort to balance the sources of error and variation towards cost-effectiveness and time-efficiency. In this effort, hydroecological data from geographically and hydrologically various river types and in different time periods, often collected within different projects, are either treated separately to develop site-and season-specific criteria or are aggregated to increase sample size and/or extend the geographical and typological applicability of a model [21][22][23]. In BMI-based studies, typical aggregation schemes include spatiotemporal pooling-of samples from different sites and/or seasons-without pre-treatment [17,24]; spatial aggregation of samples only from specific, usually low-flow periods [25,26]; and spatiotemporal pooling of samples after proper pre-treatment [4,19,27].…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal Variation in Benthic-Invertebrates-Based Physical Habitat Modelling: Can We Use Generic Instead of Local and Season-Specific Habitat Suitability Criteria?

Theodoropoulos

Skoulikidis

Stamou

et al. 2018

Water

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Generic habitat suitability criteria (HC) are often developed from spatially and temporally variable hydroecological datasets to increase generality, cost-effectiveness, and time-efficiency of habitat models. For benthic macroinvertebrates (BMIs), however, there is no prior knowledge on the spatiotemporal variation in their habitat preferences and how this may be reflected in the final environmental flow (e-flow) predictions. In this study, we used a large, spatiotemporally variable BMI-hydroecological dataset and developed generic, local, and season-specific subsets of HC for three seasons and two river types within various data pre-treatment options. Each subset was used to train a fuzzy habitat model, predict the habitat suitability in two hydrodynamically-simulated river reaches, and develop/compare model-based e-flow scenarios. We found that BMIs shift their habitat preferences among seasons and river types; consequently, spatiotemporally variable e-flow predictions were developed, with the seasonal variation being greater than the typological one. Within this variation, however, we found that with proper data pre-treatment, the minimum-acceptable e-flows from the generic models mostly (65–90%) lay within the acceptable e-flows predicted by the local and season-specific models. We conclude that, within specific limitations, generic BMI-HC can be used for geographically extended, cost-effective e-flow assessments, compensating for the within-limits loss of predictive accuracy.

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Environmental flow assessment for benthic macroinvertebrate communities using pseudo‐2D hydraulic habitat modelling at a green small hydropower plant

Hu,

Feng,

et al. 2023

Ecohydrology

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The determination of minimum flow requirements for green small hydropower plants (GSHP) in China primarily relies on hydrological methods such as the Tennant method with no seasonal variation. However, the direct application of hydrological methods without local ecological data for calibration lacks ecological validity, potentially resulting in unsuitable minimum flow recommendations for local aquatic biota. Hydraulic‐habitat modelling (HHM) is assumed to provide more ecologically relevant and reliable environmental flow recommendations (EFRs), but benthic macroinvertebrates (BMs), crucial in the aquatic food web, have rarely been the focus in HHM studies. Moreover, the strong subjectivity in HHM processes hinders the comparison of EFRs across different biota and geographical regions. This study aims to investigate the ecological validity of using the Tennant method to set minimum flow requirements for local BM communities and the impacts of various methods used in HHM on derived EFRs. To achieve this, a pseudo‐2D HHM approach is employed, integrating the 1D hydraulic models HEC‐RAS and CASiMiR with the habitat model HABFUZZ. The EFRs downstream of Jiufeng reservoir, one of China's first GSHPs, are derived for wet (April–June) and dry seasons (July–September). Our findings highlight that setting minimum flow alone is inadequate for preserving BM community integrity downstream of GSHPs. It is crucial to incorporate more diverse environmental flow criteria, including minimum flows and peak flows, into GSHP assessment standards, with recommended flow levels varying across different seasons. Additionally, the development of a standardized HHM methodology is essential to mitigate the inherent subjectivity in HHM and facilitate the comparison of EFRs generated from different studies. This study's innovative modelling framework and findings will enhance the optimization of minimum flow assessment criteria for GSHP in China, deepen understanding of seasonal e‐flow requirements of BM communities, and refine the methodology used in BM HHM for e‐flow recommendation.

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Ecosystem‐based environmental flow assessment in a Greek regulated river with the use of 2D hydrodynamic habitat modelling

Cited by 35 publications

References 37 publications

Comparing environmental flow scenarios from hydrological methods, legislation guidelines, and hydrodynamic habitat models downstream of the Marathon Dam (Attica, Greece)

Comparing environmental flow scenarios from hydrological methods, legislation guidelines, and hydrodynamic habitat models downstream of the Marathon Dam (Attica, Greece)

Spatiotemporal Variation in Benthic-Invertebrates-Based Physical Habitat Modelling: Can We Use Generic Instead of Local and Season-Specific Habitat Suitability Criteria?

Environmental flow assessment for benthic macroinvertebrate communities using pseudo‐2D hydraulic habitat modelling at a green small hydropower plant

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