Investigating the respective impacts of groundwater exploitation and climate change on wetland extension over 150 years

Landes, Antoine Armandine Les; Aquilina, Luc; Ridder, Jo De; Longuevergne, Laurent; Pagé, Christian; Goderniaux, Pascal

doi:10.1016/j.jhydrol.2013.11.039

Cited by 22 publications

(7 citation statements)

References 41 publications

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“…For a detailed discussion of capture and groundwater depletion, see Konikow and Leake (). Depending on what is deemed as acceptable consequences (environmental, economic, and social) of the groundwater depletion and the effects of any induced recharge or reduced discharge such as decreased springflow or streamflow or drying lakes and wetlands, the development and use of groundwater may or may not be considered sustainable (Alley et al ; Armandine et al ).…”

Section: Introductionmentioning

confidence: 99%

Assessing Groundwater Depletion and Dynamics Using GRACE and InSAR: Potential and Limitations

Castellazzi¹,

et al. 2016

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In the last decade, remote sensing of the temporal variation of ground level and gravity has improved our understanding of groundwater dynamics and storage. Mass changes are measured by GRACE (Gravity Recovery and Climate Experiment) satellites, whereas ground deformation is measured by processing synthetic aperture radar satellites data using the InSAR (Interferometry of Synthetic Aperture Radar) techniques. Both methods are complementary and offer different sensitivities to aquifer system processes. GRACE is sensitive to mass changes over large spatial scales (more than 100,000 km 2 ). As such, it fails in providing groundwater storage change estimates at local or regional scales relevant to most aquifer systems, and at which most groundwater management schemes are applied. However, InSAR measures ground displacement due to aquifer response to fluid-pressure changes. InSAR applications to groundwater depletion assessments are limited to aquifer systems susceptible to measurable deformation. Furthermore, the inversion of InSAR-derived displacement maps into volume of depleted groundwater storage (both reversible and largely irreversible) is confounded by vertical and horizontal variability of sediment compressibility. During the last decade, both techniques have shown increasing interest in the scientific community to complement available in situ observations where they are insufficient. In this review, we present the theoretical and conceptual bases of each method, and present idealized scenarios to highlight the potential benefits and challenges of combining these techniques to remotely assess groundwater storage changes and other aspects of the dynamics of aquifer systems.

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Section: Introductionmentioning

confidence: 99%

Assessing Groundwater Depletion and Dynamics Using GRACE and InSAR: Potential and Limitations

Castellazzi¹,

et al. 2016

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“…Printer-friendly version Discussion paper (e.g. Ala-aho et al, 2017;Armandine Les Landes et al, 2014;Haahti et al, 2016;Hammersmark et al, 2008;House et al, 2016;Li et al, 2019). The excellent fit of simulated long-term mean groundwater table depth, groundwater upwelling rate and groundwater seepage rate with observed mire boundaries (including along the narrow valley downstream and in the small sub-basins located upstream of and 30m above the main mire extent where no groundwater table depth data were available for calibration) demonstrates that the model satisfactorily reproduces the dominant hydrological characteristics of the mire and its catchment.…”

Section: Hessdmentioning

confidence: 84%

“…Calibration and validation periods covering a total duration of 3 years (and often much less) are the norm rather than the exception in physically-based hydrological modelling studies of wetlands (e.g. Ala-aho et al, 2017;Armandine Les Landes et al, 2014;Haahti et al, 2016;House et al, 2016;Levison et al, 2014;Li et al, 2019;Quillet et al, 2017;Thompson et al, 2004). In many cases this is the result of the unfortunate exclusion of wetland environments from formal hydrometric networks (e.g.…”

Section: Response To Commentmentioning

confidence: 99%

Response to Referee #1

Duranel¹

2020

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“…Uncertainties are particularly high when it comes to groundwater resources [16]. Most studies [16][17][18][19][20][21] have been focused on the climate change impacts on surface water, often neglecting groundwater, which is more complicated to model and assumed to be less vulnerable to climate change. Moreover, few [22][23][24] have considered large-scale, fully-integrated hydrological models when investigating climate change impacts.…”

Section: Introductionmentioning

confidence: 99%

High-Resolution, Integrated Hydrological Modeling of Climate Change Impacts on a Semi-Arid Urban Watershed in Niamey, Niger

Boko

Konaté

Yalo

et al. 2020

Water

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This study evaluates the impact of climate change on water resources in a large, semi-arid urban watershed located in the Niamey Republic of Niger, West Africa. The watershed was modeled using the fully integrated surface–subsurface HydroGeoSphere model at a high spatial resolution. Historical (1980–2005) and projected (2020–2050) climate scenarios, derived from the outputs of three regional climate models (RCMs) under the regional climate projection (RCP) 4.5 scenario, were statistically downscaled using the multiscale quantile mapping bias correction method. Results show that the bias correction method is optimum at daily and monthly scales, and increased RCM resolution does not improve the performance of the model. The three RCMs predicted increases of up to 1.6% in annual rainfall and of 1.58 °C for mean annual temperatures between the historical and projected periods. The durations of the minimum environmental flow (MEF) conditions, required to supply drinking and agricultural water, were found to be sensitive to changes in runoff resulting from climate change. MEF occurrences and durations are likely to be greater from 2020–2030, and then they will be reduced for the 2030–2050 statistical periods. All three RCMs consistently project a rise in groundwater table of more than 10 m in topographically high zones, where the groundwater table is deep, and an increase of 2 m in the shallow groundwater table.

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Investigating the respective impacts of groundwater exploitation and climate change on wetland extension over 150 years

Cited by 22 publications

References 41 publications

Assessing Groundwater Depletion and Dynamics Using GRACE and InSAR: Potential and Limitations

Assessing Groundwater Depletion and Dynamics Using GRACE and InSAR: Potential and Limitations

Response to Referee #1

High-Resolution, Integrated Hydrological Modeling of Climate Change Impacts on a Semi-Arid Urban Watershed in Niamey, Niger

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