Identifying watershed-scale barriers to groundwater flow: Lineaments in the Canadian Shield

Gleeson, Tom; Novakowski, Kent

doi:10.1130/b26241.1

Cited by 41 publications

(29 citation statements)

References 70 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The barrier effect due to fault gouge has been reported elsewhere for such fault zones through Precambrian rocks in other geological contexts [20]; [21]. Actually, rains are abundant (between 1600 mm and 1800 mm) and reach a peak around June and July.…”

Section: General Information Of the Study Areamentioning

confidence: 97%

Discontinuous Nature of Phreatic Aquifers in Granitic Rocks at Watershed Scale: A Stratiform Model from Perennial Streams and Well Data

Yao

Fouché

Kouadio

et al. 2017

Asian Review of Environmental and Earth Sciences

View full text Add to dashboard Cite

The study was carried out within 4,000 km 2 segment of Sassandra watershed located in Soubré, south-west of Côte d'Ivoire where coffee and cocoa production are preponderant. This work aimed to provide a general methodology in order to draw the flow directions and map the potential productive aquifer in hard-rocks. Drilling data, remote sensing, and geomorphic data in a context of weathered plutonic and metamorphic Precambrian were used. The regional water table was modeled through a linear relationship between the topographic surface of the digital elevation model and the base surface of the perennial streams thalwegs. As result, a map of regolith thickness obtained has been compared with the geology to emphasize their relationship. Furthermore, other correlations have been found between the hydraulic data and geomorphological features to get more precise stratification model. Concealed by the regolith, the hard-rock aquifer is made up of three layers. From top to bottom we have the saprolite (< 10 m), the weathering induced fissured layer (35 m mean thickness) below the base of the saprolite and finally, the unweathered with very low hydraulic conductivity. Each layer is characterized by a constant density of water-bearing fissures. This shows the impact of a stratiform weathering profile on the layering of the aquifer. High variability of observing yields is mainly due to thickness heterogeneity of the higher-storage regolith and underlying higher-conductive fissured saprock. Also, the wells tapping water under a regolith with medium or high thickness were the most productive justifying that regolith thickness mapping is a first rank tool in hydrogeology prospecting. The thickness map obtained from the interpolated base surface of the regolith and the DEM represents a useful tool for groundwater management.

show abstract

Section: General Information Of the Study Areamentioning

confidence: 97%

Discontinuous Nature of Phreatic Aquifers in Granitic Rocks at Watershed Scale: A Stratiform Model from Perennial Streams and Well Data

Yao

Fouché

Kouadio

et al. 2017

Asian Review of Environmental and Earth Sciences

View full text Add to dashboard Cite

show abstract

“…Such a vertical displacement appears to be manifest as fairly steep valley slopes (6.121 Â 10 À4 m m À1 ) for this reach of the River Gargar, with the high channel sinuosity (3.195) developing to maintain fairly typical Gargar channel water surface slopes (5.65 Â 10 À5 m m À1 ) across the slight vertical displacement of the lineament (Woodbridge, 2013). The EeW meander orientation for this reach most probably is related to the approximate EeW orientation of the lineament and associated joints, especially since they may act as hydraulic conduits or barriers (Park, 1997;Gleeson and Novakowski, 2009;Gay, 2012). The River Karun (Shuteyt) and the River Dez flow across this extensive structural lineament with no notable geomorphological modifications (Fig.…”

Section: Interactions Between Artificial River Development and Earth mentioning

confidence: 99%

Characteristics of direct human impacts on the rivers Karun and Dez in lowland south-west Iran and their interactions with earth surface movements

Woodbridge

Parsons

Heyvaert

et al. 2016

Quaternary International

View full text Add to dashboard Cite

a b s t r a c tTwo of the primary external factors influencing the variability of major river systems, over river reach scales, are human activities and tectonics. Based on the rivers Karun and Dez in south-west Iran, this paper presents an analysis of the geomorphological responses of these major rivers to ancient human modifications and tectonics. Direct human modifications can be distinguished by both modern constructions and ancient remnants of former constructions that can leave a subtle legacy in a suite of river characteristics. For example, the ruins of major dams are characterised by a legacy of channel widening to 100's up to c. 1000 m within upstream zones that can stretch to channel distances of many kilometres upstream of former dam sites, whilst the legacy of major, ancient, anthropogenic river channel straightening can also be distinguished by very low channel sinuosities over long lengths of the river course. Tectonic movements in the region are mainly associated with young and emerging folds with NW eSE and NeS trends and with a long structural lineament oriented EeW. These earth surface movements can be shown to interact with both modern and ancient human impacts over similar timescales, with the types of modification and earth surface motion being distinguishable. This paper examines the geomorphological evidence and outlines the processes involved in the evolution of these interactions through time. The analysis shows how interactions between earth surface movements and major dams are slight, especially after ancient dam collapse. By contrast, interactions between earth surface movements and major anthropogenic river channel straightening are shown to be a key factor in the persistence of long, near-straight river courses. Additionally, it is suggested that artificial river development, with very limited river channel lateral migration, may promote incision across an active fold at unusually long distances from the fold "core" and may promote markedly increased sinuosity across a structural lineament.

show abstract

“…Groundwater flow at depth depends on rock porosity, fracture aperture distribution and connectivity of the fracture network. Specifically, fault zones can affect a large area of a massif and can greatly influence fluid flow at the regional scale (Bense and Person, 2006;Bense et al, 2013;Evans et al, 1997;Forster and Evans, 1991;Gleeson and Novakowski, 2009;Rojstaczer et al, 1995). Fault zones are characterized by an internal structural complexity (Bense et al, 2013;Caine et al, 1996) which control their capacity to drain or to act as barrier to groundwater flow.…”

Section: Introductionmentioning

confidence: 99%

Groundwater sources and geochemical processes in a crystalline fault aquifer

Roques

Aquilina

Bour

et al. 2014

Journal of Hydrology

View full text Add to dashboard Cite

International audienceThe origin of water flowing in faults and fractures at great depth is poorly known in crystalline media.This paper describes a field study designed to characterize the geochemical compartmentalization of adeep aquifer system constituted by a graben structure where a permeable fault zone was identified. Analysesof the major chemical elements, trace elements, dissolved gases and stable water isotopes reveal theorigin of dissolved components for each permeable domain and provide information on various watersources involved during different seasonal regimes. The geochemical response induced by performinga pumping test in the fault-zone is examined, in order to quantify mixing processes and contributionof different permeable domains to the flow. Reactive processes enhanced by the pumped fluxes are alsoidentified and discussed.The fault zone presents different geochemical responses related to changes in hydraulic regime. Theyare interpreted as different water sources related to various permeable structures within the aquifer.During the low water regime, results suggest mixing of recent water with a clear contribution of olderwater of inter-glacial origin (recharge temperature around 7 C), suggesting the involvement of watertrapped in a local low-permeability matrix domain or the contribution of large scale circulation loops.During the high water level period, due to inversion of the hydraulic gradient between the major permeablefault zone and its surrounding domains, modern water predominantly flows down to the deep bedrockand ensures recharge at a local scale within the graben.Pumping in a permeable fault zone induces hydraulic connections with storage-reservoirs. The overlaidregolith domain ensures part of the flow rate for long term pumping (around 20% in the present case).During late-time pumping, orthogonal fluxes coming from the fractured domains surrounding the majorfault zone are dominant. Storage in the connected fracture network within the graben structure mainlyensures the main part of the flow rate (80% in the present case). Reactive processes are induced by mixingof water from different sources and transfer conditions. A specific approach is applied to quantify thereaction rate involved along the pumping time. Autotrophic denitrification coupled with iron mineralsoxidation is highlighted and water rock interaction is clearly enhanced by the flux changes induced bypumping

show abstract

Identifying watershed-scale barriers to groundwater flow: Lineaments in the Canadian Shield

Cited by 41 publications

References 70 publications

Discontinuous Nature of Phreatic Aquifers in Granitic Rocks at Watershed Scale: A Stratiform Model from Perennial Streams and Well Data

Discontinuous Nature of Phreatic Aquifers in Granitic Rocks at Watershed Scale: A Stratiform Model from Perennial Streams and Well Data

Characteristics of direct human impacts on the rivers Karun and Dez in lowland south-west Iran and their interactions with earth surface movements

Groundwater sources and geochemical processes in a crystalline fault aquifer

Contact Info

Product

Resources

About