Process-based modelling to evaluate simulated groundwater levels and frequencies in a Chalk catchment in south-western England

Brenner, Simon; Coxon, Gemma; Howden, Nicholas J K; Freer, J. E.; Hartmann, Andreas

doi:10.5194/nhess-18-445-2018

Cited by 29 publications

(12 citation statements)

References 85 publications

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“…Piezometric levels obtained by KAGIS reported good agreement between the observed and simulated values. Similar trustworthy results were also obtained in the simulation of the karst groundwater levels in previous studies (e.g., Adinehvand, Raeisi, & Hartmann, 2017;Brenner, Coxon, Howden, Freer, & Hartmann, 2018). In the present study, main differences between the observed and simulated values were identified between September 2009 and September 2011, probably related to the abovementioned problems in the measurement of the experimental values.…”

Section: Modelled Resultssupporting

confidence: 92%

Validating the KAGIS black‐box GIS‐based model in a Mediterranean karst aquifer: Case of study of Mela aquifer (SE Spain)

Valdés-Abellán

Pla

Fernández-Mejuto

et al. 2018

Hydrological Processes

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Karst Aquifer GIS‐based model (KAGIS model) is developed and applied to Mela aquifer, a small karst aquifer located in a Mediterranean region (SE Spain). This model considers different variables, such as precipitation, land use, surface slope and lithology, and their geographical heterogeneity to calculate both, the run‐off coefficients and the fraction of precipitation which contributes to fill the soil water reservoir existing above the aquifer. Evapotranspiration uptakes deplete water, exclusively, from this soil water reservoir and aquifer recharge occurs when water in the soil reservoir exceeds the soil field capacity. The proposed model also obtains variations of the effective porosity in a vertical profile, an intrinsic consequence of the karstification processes. A new proposal from the Nash–Sutcliffe efficiency index, adapted to arid environments, is presented and employed to evaluate the model's ability to predict the water table oscillations. The uncertainty in the model parameters is determined by the Generalized Likelihood Uncertainty Estimation method. Afterwards, when KAGIS is calibrated, wavelet analysis is applied to the resulting data in order to evaluate the variability in the aquifer behaviour. Wavelet analysis reveals that the rapid hydrogeological response, typical of a wide variety of karst systems, is the prevailing feature of Mela aquifer. This study proves that KAGIS is a useful tool to quantify recharge and discharge rates of karst aquifers and can be effectively applied to develop a proper management of water resources in Mediterranean areas.

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Section: Modelled Resultssupporting

confidence: 92%

Validating the KAGIS black‐box GIS‐based model in a Mediterranean karst aquifer: Case of study of Mela aquifer (SE Spain)

Valdés-Abellán

Pla

Fernández-Mejuto

et al. 2018

Hydrological Processes

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“…The study reinforces the concept that the chalk aquifer is heterogeneous and should be treated as a karst aquifer (e.g., El Janyani et al, 2014;Valdes et al, 2014;Chédeville et al, 2015;Delbart et al, 2016;Grube et al, 2017 andBrenner et al, 2018). The evidence from our study indicates that conduit development in the Chalk is often guided by hardgrounds, sheet/semi-tabular flint bands and marl seams (section 5.1).…”

Section: Implications For Chalk Hydrogeologysupporting

confidence: 88%

“…In practice, in many areas, the functioning of the Chalk groundwater system is rather more similar to a karst aquifer than a granular or single porosity media (Bloomfield et al, 2013;Barhoum et al, 2014). Flow velocities measured from tracer tests can be >300-400 m h -1 (Maurice et al, 2006;Keim et al, 2012) and spring discharges in excess of 5 m 3 s −1 (Brenner et al, 2018). For these reasons, an increasing number of hydrogeological studies consider the Chalk as a triple porosity aquifer, with a combination of fracture and matrix porosity, and localized karst permeability (Mangin, 1975;Pennequin et al, 2017), or just as a karst aquifer in which karstification is less well developed than in other more massive and indurated limestones (Maurice et al, 2006;El Janyani et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Notwithstanding the above, the Chalk aquifer is still far too often visualized as a homogeneous porous medium (Brenner et al, 2018), rather than a karstic aquifer. Only a few studies have considered the role of lithological heterogeneity and stratigraphical discontinuities on groundwater flow (Descostes et al, 2012;Gallagher et al, 2012;Barhoum et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

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Stratigraphical influence on chalk cave development in Upper Normandy, France: implications for chalk hydrogeology

Ballesteros¹,

Farrant²,

Nehmé³

et al. 2020

IJS

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Classically, the Upper Cretaceous Chalk Group aquifer of northwest Europe is conceptualized as a homogenous dual-porosity aquifer, with high porosity related to its fine-grained porous matrix, and intermediate hydraulic conductivity associated with fractures. However, an increasing number of hydrological studies visualize the Chalk as a heterogeneous karst aquifer due to the localised presence of dissolutionally enlarged conduits. Field investigation suggests that cave development is guided by distinct stratigraphical and tectonic discontinuities within the rock mass. Identifying which potential inception horizons within the Chalk aquifer are favoured, and why, is important for developing future robust conceptual models of groundwater behaviour. This study focusses on the Chalk of the Upper Normandy region in France where karstic conduits are common and are linked to major sources of groundwater for public water supply. We analyse the geometry and geomorphology of six chalk caves exposed in the Seine Valley with an aggregated length of over 5.7 km, along with other caves in southern England, and identify the key inception horizons associated with their development. The data shows that prominent Turonian, Coniacian and Santonian hardgrounds have influenced the development of 68% of the studied caves length, with sheet-flints and marl seams also playing a prominent role. Caves developed on or between hardgrounds typically display a complex interlinked anastomotic passage network, whereas passages subjected to paragenetic conditions caused by a high sediment flux tend to be concentrated into fewer, larger conduits. The new evidence from Normandy and Southern England demonstrates the role of lithostratigraphy, and in particular stratigraphical discontinuities on conduit development. The data reinforces the idea that the Chalk aquifer should be viewed as a heterogeneous triple porosity karstic aquifer, in which conduit development is influenced by key stratigraphical discontinuities. This improved conceptual model can be used to develop better groundwater flow models and improved catchment delineation.

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“…Jackson et al (2015) utilised a distributed ZOOMQ3D groundwater model of the chalk aquifer, with various emission scenario input data, to investigate the predicted changes in groundwater levels. Brenner et al (2018) conducted a further study of this chalk catchment and showed that projected climate changes may lead to generally lower groundwater levels and a reduction in exceedances of high groundwater level percentiles in the future. Chen et al (2018) conducted a study into the effects of climate change on alpine karst using GCM data.…”

Section: Introductionmentioning

confidence: 99%

Impacts of climate change on groundwater flooding and ecohydrology in lowland karst

Morrissey

Nolan

McCormack

et al. 2021

Hydrol. Earth Syst. Sci.

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Abstract. Lowland karst aquifers can generate unique wetland ecosystems which are caused by groundwater fluctuations that result in extensive groundwater–surface water interactions (i.e. flooding). However, the complex hydrogeological attributes of these systems, linked to extremely fast aquifer recharge processes and flow through well-connected conduit networks, often present difficulty in predicting how they will respond to changing climatological conditions. This study investigates the predicted impacts of climate change on a lowland karst catchment by using a semi-distributed pipe network model of the karst aquifer populated with output from the high spatial resolution (4 km) Consortium for Small-scale Modelling Climate Lokalmodell (COSMO-CLM) regional climate model simulations for Ireland. An ensemble of projections for the future Irish climate were generated by downscaling from five different global climate models (GCMs), each based on four Representative Concentration Pathways (RCPs; RCP2.6, RCP4.5, RCP6.0 and RCP8.5) to account for the uncertainty in the estimation of future global emissions of greenhouse gases. The one-dimensional hydraulic/hydrologic karst model incorporates urban drainage software to simulate open channel and pressurised flow within the conduits, with flooding on the land surface represented by storage nodes with the same stage volume properties of the physical turlough basins. The lowland karst limestone catchment is located on the west coast of Ireland and is characterised by a well-developed conduit-dominated karst aquifer which discharges to the sea via intertidal and submarine springs. Annual above ground flooding associated with this complex karst system has led to the development of unique wetland ecosystems in the form of ephemeral lakes known as turloughs; however, extreme flooding of these features causes widespread damage and disruption in the catchment. This analysis has shown that mean, 95th and 99th percentile flood levels are expected to increase by significant proportions for all future emission scenarios. The frequency of events currently considered to be extreme is predicted to increase, indicating that more significant groundwater flooding events seem likely to become far more common. The depth and duration of flooding is of extreme importance, both from an ecological perspective in terms of wetland species distribution and for extreme flooding in terms of the disruption to homes, transport links and agricultural land inundated by flood waters. The seasonality of annual flooding is also predicted to shift later in the flooding season, which could have consequences in terms of ecology and land use in the catchment. The investigation of increasing mean sea levels, however, showed that anticipated rises would have very little impact on groundwater flooding due to the marginal impact on ebb tide outflow volumes. Overall, this study highlights the relative vulnerability of lowland karst systems to future changing climate conditions, mainly due to the extremely fast recharge which can occur in such systems. The study presents a novel and highly effective methodology for studying the impact of climate change in lowland karst systems by coupling karst hydrogeological models with the output from high-resolution climate simulations.

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Process-based modelling to evaluate simulated groundwater levels and frequencies in a Chalk catchment in south-western England

Cited by 29 publications

References 85 publications

Validating the KAGIS black‐box GIS‐based model in a Mediterranean karst aquifer: Case of study of Mela aquifer (SE Spain)

Validating the KAGIS black‐box GIS‐based model in a Mediterranean karst aquifer: Case of study of Mela aquifer (SE Spain)

Stratigraphical influence on chalk cave development in Upper Normandy, France: implications for chalk hydrogeology

Impacts of climate change on groundwater flooding and ecohydrology in lowland karst

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