Reservoir longitudinal gradient promotes ordered losses on diversity and density of Ephemeroptera community

Melo, Sandra Maria de; Pinha, Gisele Daiane; Ragonha, Flávio Henrique; Fontes-Junior, H. M.; Takeda, Alice Michiyo

doi:10.1590/1519-6984.181514

Cited by 4 publications

(3 citation statements)

References 36 publications

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“…Longitudinal gradients in fish distribution and composition have been attributed to spatial changes in the reservoir trophic state (Buynak et al 1989;Hubert and O'Shea 1992;Michaletz 1998;Prchalová et al 2009), but inconsistent spatial trends among seasons and limited habitat associations suggest that additional factors contributed to the spatial variability observed in this study. Spatial segregation in large reservoirs has been influenced by seasonal spawning and movement patterns (McCarraher et al 1971;Douglas and Jahn 1987;O'Gorman et al 1991), distribution of available forage (Bowlby and Hoyle 2011;Voutilainen et al 2016;Melo et al 2018), and substrate composition (Johnson et al 1988;Sammons and Bettoli 1999). Longitudinal variability in size structure may be a result of increased structural complexity (Lewin et al 2004), macroinvertebrate production (Pamplin et al 2006;Schneider and Winemiller 2008;Whitmore et al 2017), and turbidity (Abrahams and Kattenfeld 1997) in the upper reservoir zone, which may provide conditions favorable for small or juvenile fish to avoid larger, sight-feeding predators.…”

Section: Discussionmentioning

confidence: 99%

Spatial and Temporal Variability in a Large‐Reservoir Fish Assessment and Application of a Stratified Random Sampling Approach

Schall

Schoenebeck

Koupal

2019

N American J Fish Manag

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Sampling is often standardized with regard to time and space to monitor population characteristics. Effective sampling of large reservoirs can be complicated by the inherit bias of habitat variability along the reservoir gradient. Our objective was to assess spatial and seasonal distribution patterns of target and nontarget fish species in a large reservoir to identify potential sources of bias. A multitude of fish community and habitat characteristics were measured during seasonal (spring, summer, and fall) gill‐net surveys in 2015 and 2016 at Lake McConaughy, Nebraska. Spatial assessments along the longitudinal gradient (up‐reservoir to down‐reservoir) and between opposing shorelines were made for fish metrics from the seven most common species, and associations between species‐specific relative abundance and habitat data were examined. Spatial differences in relative abundance and size structure occurred for nearly all species, with the greatest spatial variability occurring between the upper and lower reservoir zones, but few strong correlations were observed between species‐specific relative abundances and habitat data. Seasonal differences occurred in relative abundance and size structure for most species, and size structure was lowest in the fall for most species. To reduce the impact of spatial variability, we determined the minimum required sampling effort to achieve precise estimates of mean catch per net‐night using two resampling strategies, with 16 or fewer gill‐net sets required for five of seven species and 14 or fewer required if a stratified random approach is utilized. This research quantifies the extent of spatial and temporal variability in standardized sampling on a large reservoir and provides novel insight for managers of similar systems considering a stratified random approach to reduce sampling effort while maintaining desired levels of precision.

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Section: Discussionmentioning

confidence: 99%

Spatial and Temporal Variability in a Large‐Reservoir Fish Assessment and Application of a Stratified Random Sampling Approach

Schall

Schoenebeck

Koupal

2019

N American J Fish Manag

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“…These zones are the riverine, the transition, and the lacustrine zones. The riverine zone is the upstream part of the reservoir, where water still preserves a significant proportion of its velocity (Melo et al, 2018). The transitional zone is in the middle of the reservoir, and it has a lower velocity than the riverine zone.…”

Section: Water Quality (Physical and Chemical Parameters)mentioning

confidence: 99%

Comprehensive Assessment for the Potential Environmental Impacts of the Grand Ethiopian Renaissance Dam on the Downstream Countries: Itaipu Dam in the Rearview Mirror

Morsy

Abdelatif

Mostafa

2021

Air, Soil and Water Research

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This article provides a comparative environmental assessment for the Grand Ethiopian Renaissance Dam (GERD) learning from Itaipu dam experience. The article gives a full insight about the potential political and technical concerns that may affect the downstream countries as a result of the construction of GERD and proposed a solution and way forward for the negotiation based on joint collaboration perspective. Based on the analytical comparison conducted between GERD and Itaipu, the results showed that the total annual carbon dioxide (CO2) emissions expected to be released from the GERD during the operation is 3,927 tCO2eq, while other secondary emissions were estimated to be 16.17 tons, mainly of carbon monoxide and nitrogen oxides. Also, the ratio of power generation to reservoir capacity of the GERD was questionable, since Ethiopia has announced that the dam is built only for power generation and that there is no intention to utilize water from the dam reservoir. On the other side, the water quality - represented in turbidity, total suspended solids (TSS), dissolved oxygen (DO), total phosphorus (TP), and chemical oxygen demand (COD) - behind the GERD is expected to deteriorate dramatically. Also, an increase in total nitrogen (TN) is expected to occur depending on human activities. Accordingly, the article discussed thoughtfully the potential adverse impacts of the GERD on downstream countries and the possible mitigation options. The article also extended to discuss proposals for practical solutions that pave the road for joint collaboration between the three countries to achieve a transparent resolution and a fair resources utilization.

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“…In longitudinal reservoir zonation, species distributions are influenced by the range of environmental factors (Mee et al, 2018). Consequently, variation in species composition between regions (beta diversity) is expected to occur (Becker et al, 2016;Melo et al, 2018). A decrease in both abundance and species richness would then be expected from the riverine to the lacustrine region (Oliveira et al, 2010;Vašeka et al, 2016).…”

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Distribution of Siluriformes in a river under the influence of a small hydroelectric power plant of the Paraná River Basin, Brazil

Garcia

Ota

Ferreira

et al. 2020

Iheringia, Sér. Zool.

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ABSTRACT When a river is dammed, impacts differ according to distance from the dam under consideration, and sites closer to the dam are more affected than distant ones. Damming a river changes the flow and landscape characteristics, which, in turn, change the hydrological, limnological and ecological dynamics, such as biological production, species distribution, and ecosystem structuring, functioning and services. This study evaluates the distribution pattern of the Siluriformes (catfish) fish species near a small hydroelectric power plant in the Jaguariaíva River, considering three distinct distances from the dam: upstream region, reservoir and downstream region. Samples were taken with gillnets between March 2013 and December 2014. The abundance and richness of the Siluriformes species were evaluated. A permutational multivariate analysis of variance was used to access possible differences in species composition among sites. Finally, a permutational analysis of multivariate dispersion was used to assess possible differences among sampling sites and to examine composition similarities among sites. A total of 840 Siluriformes individuals were captured, distributed among ten species and four families. The highest richness was observed in the downstream region, while the lowest richness was observed in the reservoir area. Differences in the abundance of species were observed between the three distinct regions; the downstream region presented the highest species abundance (CPUE), whereas the lowest abundance was observed in the dam region. Hypostomus paulinus and Hypostomus strigaticeps were abundant species, but exclusively sampled in the downstream region, while Corydoras ehrhardti and Cambeva diabola presented their highest abundance in the upstream region. The distinct longitudinal distribution of Siluriformes observed in this study can be interpreted as indicative of the negative effects of damming. Our study suggests that building small dams may result in negative impacts on the fish assemblage, impacts comparable to those of large reservoirs in terms of spatial changes. It is fundamentally necessary to better evaluate the environmental impacts of small dams in the Neotropical region, especially because few is known about them and how such impacts are comparable to impacts of larger reservoirs.

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Reservoir longitudinal gradient promotes ordered losses on diversity and density of Ephemeroptera community

Cited by 4 publications

References 36 publications

Spatial and Temporal Variability in a Large‐Reservoir Fish Assessment and Application of a Stratified Random Sampling Approach

Spatial and Temporal Variability in a Large‐Reservoir Fish Assessment and Application of a Stratified Random Sampling Approach

Comprehensive Assessment for the Potential Environmental Impacts of the Grand Ethiopian Renaissance Dam on the Downstream Countries: Itaipu Dam in the Rearview Mirror

Distribution of Siluriformes in a river under the influence of a small hydroelectric power plant of the Paraná River Basin, Brazil

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