Summer Season Water Temperature Modeling under the Climate Change: Case Study for Fourchue River, Quebec, Canada

Kwak, Jaewon; St‐Hilaire, André; Chebana, Fateh; Kim, Gilho

doi:10.3390/w9050346

Cited by 26 publications

(12 citation statements)

References 55 publications

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“…Although Kwak et al (2017) reported a relatively small increase in median June temperature (0.2 -0.7 °C increase in mean June temperature by 2096), the results of our study are broadly consistent with the findings of Daigle et al (2015;0.7-2.7 °C increase in seven-day maximum temperature by 2065), thus adding credence to our projected increase in annual maximum and summer minimum river temperature towards 2100. However, both Kwak et al (2017) and Daigle et al (2015) were conducted in substantially smaller watersheds than the SJR, so limited inferences can be drawn as to their comparability.…”

Section: Ecologically Relevant Temperature Metricssupporting

confidence: 90%

“…Physiographic data necessary to run CEQUEAU's hydrological model component were assembled from a range of GIS databases. Elevations were derived from a 1 arc-second (~25 m) SRTM digital elevation model (Farr et al, 2007), while raster land use data used to compute forest and bare soil cover were obtained from the North American Land-Change Monitoring System (Latifovic et al, 2012). Percentage cover of waterbodies and wetlands were obtained from vector shapefiles downloaded from the Government of New Brunswick's GeoNB geospatial data portal (http://www.snb.ca/geonb1/e/index-E.asp).…”

Section: Study Areamentioning

confidence: 99%

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Impact of Future Climate Change on Water Temperature and Thermal Habitat for Keystone Fishes in the Lower Saint John River, Canada

Dugdale

Curry

St‐Hilaire

et al. 2018

Water Resour Manage

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Water temperature is a key determinant of biological processes in rivers. Temperature in northern latitude rivers is expected to increase under climate change, with potentially adverse consequences for cold water-adapted species. In Canada, little is currently known about the timescales or magnitude of river temperature change, particularly in large (≥10 4 km 2 ) watersheds. However, because Canadian watersheds are home to a large number of temperature-sensitive organisms, there is a pressing need to understand the potential impacts of climate change on thermal habitats. This paper presents the results of a study to simulate the effects of climate change on the thermal regime of the lower Saint John River (SJR), a large, heavily impounded, socio-economically important watershed in eastern Canada. The CEQUEAU hydrological-water temperature model was calibrated against river temperature observations and driven using meteorological projections from a series of regional climate models. Changes in water temperature were assessed for three future periods (2030-2034, 2070-2074 and 2095-2099). Results show that mean water temperature in the In eastern Canada, particular importance is placed on understanding both the driving mechanisms of river temperature and the potential for future alterations to river temperature regimes because of the high socio-economic importance of coldwater fish species such as salmonids (FOPO, 2017).Summer water temperature in many eastern Canadian rivers regularly approaches or exceeds thermal maxima for a range of coldwater species (e.g. Mather et al., 2008;Jeong et al., 2013;Daigle et al., 2015), and temperature-related salmonid mortality events are already being observed across rivers in Québec and New Brunswick (e.g. Breau, 2013). River scientists have therefore started to use temperature models (e.g.

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Section: Ecologically Relevant Temperature Metricssupporting

confidence: 90%

Section: Study Areamentioning

confidence: 99%

Impact of Future Climate Change on Water Temperature and Thermal Habitat for Keystone Fishes in the Lower Saint John River, Canada

Dugdale

Curry

St‐Hilaire

et al. 2018

Water Resour Manage

Self Cite

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“…Two climate change scenarios were considered in this study: RCP 4.5 and RCP 8.5 scenarios. A general circulation model (GCM), with a basis in climate-assessment studies [32][33][34], provides the general circulation of the Earth's atmosphere. Although the spatial coverage is global, the grid size is too coarse for modelling wave forcings (i.e.…”

Section: First Step: Process-based Dynamical Modellingmentioning

confidence: 99%

Multivariate Hybrid Modelling of Future Wave-Storms at the Northwestern Black Sea

Lin-Ye

Garcı́a-León

Gràcia

et al. 2018

Water

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The characterization of future wave-storms and their relationship to large-scale climate can provide useful information for environmental or urban planning at coastal areas. A hybrid methodology (process-based and statistical) was used to characterize the extreme wave-climate at the northwestern Black Sea. The Simulating WAve Nearshore spectral wave-model was employed to produce wave-climate projections, forced with wind-fields projections for two climate change scenarios: Representative Concentration Pathways (RCPs) 4.5 and 8.5. A non-stationary multivariate statistical model was built, considering significant wave-height and peak-wave-period at the peak of the wave-storm, as well as storm total energy and storm-duration. The climate indices of the North Atlantic Oscillation, East Atlantic Pattern, and Scandinavian Pattern have been used as covariates to link to storminess, wave-storm threshold, and wave-storm components in the statistical model. The results show that, first, under both RCP scenarios, the mean values of significant wave-height and peak-wave-period at the peak of the wave-storm remain fairly constant over the 21st century. Second, the mean value of storm total energy is more markedly increasing in the RCP4.5 scenario than in the RCP8.5 scenario. Third, the mean value of storm-duration is increasing in the RCP4.5 scenario, as opposed to the constant trend in the RCP8.5 scenario. The variance of each wave-storm component increases when the corresponding mean value increases under both RCP scenarios. During the 21st century, the East Atlantic Pattern and changes in its pattern have a special influence on wave-storm conditions. Apart from the individual characteristics of each wave-storm component, wave-storms with both extreme energy and duration can be expected in the 21st century. The dependence between all the wave-storm components is moderate, but grows with time and, in general, the severe emission scenario of RCP8.5 presents less dependence between storm total energy and storm-duration and among wave-storm components.

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“…In addition to long-term synoptic assessment, an approach that is likely to become important to projecting the future of lake thermal properties in a warming world, is coupled modeling. In this special issue, Kwak et al [13] used a model that can simulate hydrological and thermal responses of water bodies to warming, and coupled it with output from the Coupled Model Inter-Comparison Project Phase 5 (CMIP5) Global Circulation Models (GCMs). They evaluated the projected effects of three future climate scenarios on the Fourchue River, Quebec, Canada.…”

Section: Lake Warmingmentioning

confidence: 99%

Ecological Responses of Lakes to Climate Change

Havens

Jeppesen

2018

Water

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Summer Season Water Temperature Modeling under the Climate Change: Case Study for Fourchue River, Quebec, Canada

Cited by 26 publications

References 55 publications

Impact of Future Climate Change on Water Temperature and Thermal Habitat for Keystone Fishes in the Lower Saint John River, Canada

Impact of Future Climate Change on Water Temperature and Thermal Habitat for Keystone Fishes in the Lower Saint John River, Canada

Multivariate Hybrid Modelling of Future Wave-Storms at the Northwestern Black Sea

Ecological Responses of Lakes to Climate Change

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