The Evolution of Evapotranspiration Cover Systems at Barrick Goldstrike Mines

Zhan, Guosheng; Schafer, William M.; Milczarek, Mike; Myers, K.; Giraudo, Joe; Espell, Ron

doi:10.21000/jasmr06022585

Cited by 7 publications

(9 citation statements)

References 3 publications

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“…These calculations have been complemented by laboratory experiments (Bussière et al 1998) and validated using monitoring data obtained from in situ cover systems (e.g. Bussière 1999; Bussière et al 2003a;Zhan et al 2001aZhan et al , 2006. The results obtained through these studies have shown that the behavior of inclined CCBEs is intrinsically dynamic.…”

Section: Transient Effectsmentioning

confidence: 93%

“…Stormont 1996;Bussière et al 1998;Morris and Stormont 1998;Kämpf et al 2003;Tami et al 2004) and more representative simulations that better reflect the actual field behavior of covers (e.g. Zhan et al 2001aZhan et al , 2006Bussière et al 2003a). …”

Section: Limitations Of Ross's Solution and Comparison With Other Anamentioning

confidence: 99%

“…The results obtained through these studies have shown that the behavior of inclined CCBEs is intrinsically dynamic. In fact, the diversion length is not a constant but varies in time depending on the local climatic conditions (affected by slope and Table 2 Main hydraulic properties of the simulated inclined CCBE and calculated effective length of the capillary barrier (L) for the three analytical solutions of Table 1 Brooks and Corey (1964) Gardner (1958) aspect), cover geometry and configuration, and material properties (see Bussière et al 2003b;Cifuentes et al 2006;Zhan et al 2006). This general behavior, observed in the lab, in the field, and through numerical modeling, strongly suggests that the analysis and design of inclined CCBEs should not be based on (pseudo) steady-state conditions, which in practice do not exist.…”

Section: Transient Effectsmentioning

confidence: 99%

See 2 more Smart Citations

Design of Inclined Covers with Capillary Barrier Effect by S.-E. Parent and A. Cabral

Bussière

Aubertin

Zhan³

2007

Geotech Geol Eng

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Section: Transient Effectsmentioning

confidence: 93%

Section: Limitations Of Ross's Solution and Comparison With Other Anamentioning

confidence: 99%

Section: Transient Effectsmentioning

confidence: 99%

See 1 more Smart Citation

Design of Inclined Covers with Capillary Barrier Effect by S.-E. Parent and A. Cabral

Bussière

Aubertin

Zhan³

2007

Geotech Geol Eng

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“…The effectiveness of CCBEs has been assessed in the laboratory (Bussière et al , 1998Kämpf and Montenegro 1997;Stormont and Anderson 1999;Kämpf et al 2003;Tidwell et al 2003;Yang et al 2004), in the field (Stormont 1995a;Stormont et al 1996;Aubertin et al 1997;Barth and Wohnlich 1999;von Der Hude et al 1999;Cabral et al 2007), as well as by numerical simulations (Akindunni et al 1991;Oldenburg and Pruess 1993;Bussière et al 1995Bussière et al , 2003Kämpf and Montenegro 1997;Webb 1997;Morris and Stormont 1999;Khire et al 2000;Zhan et al 2001Zhan et al , 2006Aubertin et al 2006Aubertin et al , 2009Cifuentes et al 2006).…”

Section: Basic Principles Of Capillary Barriers (Cb)mentioning

confidence: 99%

Assessment of the Design of an Experimental Cover with Capillary Barrier Effect Using 4 Years of Field Data

2011

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One important step in the design of inclined covers with capillary barrier effect (CCBE) is the determination of the water diversion length (DL). Numerical simulations can predict the DL more precisely than steady-state analytical solutions. Nevertheless, as simplified methods have always been part of engineering design, the application of analytical solutions with conservative boundary conditions, may allow engineers to make reasonable predictions, particularly during the pre-feasibility stage of a project. In this study, a CCBE was designed, constructed and instrumented at the Saint-Tite-desCaps landfill, Quebec, Canada. This CCBE included a seepage control layer superimposing a sand-gravel capillary barrier. The seepage control layer was made up of deinking by-products (DBP), an industrial byproduct that was previously disposed of as waste. The capillary barrier was designed using an adaptation of the Ross analytical solution and the scenario considered was that of steady-state flow during constant seepage flow applied uniformly at the top of the sandgravel capillary barrier. Although these conditions appear simplistic, they were deemed reasonable because placement of the seepage control layer on the top of the capillary barrier led to very low suctions at the interface, thereby allowing uniform downward seepage rates, limited by the saturated hydraulic conductivity of the DBP. In this paper, a discussion about the behaviour of the cover system based on 4 years of field data from several instruments is presented. The challenge of using DBP, more precisely the settlement of the DBP layer and its impact on k sat , is also assessed. The DL was reassessed considering the new k sat . A discussion on the validity of employing analytical solutions to determine DL is also presented. This paper illustrates how certain variables affect the design of inclined CCBEs that include a highly compressible material as seepage control layer.Keywords Cover with capillary barrier effect (CCBE) Á Diversion length Á Seepage control layer 1 Introduction

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“…An ET cover is a selfrenewing biological system and is expected to last much longer than the conventional compacted clay barrier. ET covers have been used above landfills (e.g., Albright et al, 2004;Apiwantragoon et al, 2015;Barnswell and Dwyer, 2011;Benson et al, 2001;Benson et al, 2007;Santini and Fey, 2014;Scanlon et al, 2005), waste sites (e.g., Bowerman and Redente, 1998;Gee et al, 1997;Link et al, 1995;Pettit et al, 1994;Rutqvist et al, 2011;Scanlon et al, 1997;Waugh et al, 2010;Waugh et al, 2007;Wing and Gee, 1994;Zhang, 2015), and mine lands (e.g., Barber et al, 2015;Meiers et al, 2015;O'Kane and Wels, 2003;Zhan et al, 2006). The function of an ET cover is to protect the underlying materials, provide a medium for vegetation growth, store precipitation within the cover, and release the stored precipitation later into the atmosphere so that the infiltration of precipitation waste zone is minimized.…”

Section: Introductionmentioning

confidence: 99%

Conceptual Model for Hydrology-Based Geomorphic Evapotranspiration Covers for Reclamation of Mine Land

Zhang¹,

Bugosh²,

Tesfa³

et al. 2018

JASMR

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Currently, there are about half a million abandoned mine sites in the U.S. and an estimated 15,000 in New Mexico alone. Surface mining imposes severe ecological effects on the land because it not only alters the vegetation, soils, bedrock, and landforms, but also changes the surface hydrology, groundwater, and flow paths that ultimately result in degraded ecology and water quality. Two relatively new methodologies, fluvial geomorphic landform design and evapotranspiration (ET) waste covers, offer solutions to reclaim these sites for long-term, maintenance-free reclamation. GeoFluv TM is a specific geomorphic grading design method that uses natural analogues for post-mining landscapes and uses design input values taken from stable natural landscapes to make a reclamation design that provides hydrological function, supports ecosystem integrity, and is cost-effective, sustainable, and more visually attractive. It has documented ability to produce surface runoff water quality at least equal to adjacent undisturbed lands and has been used for disturbed lands, including active and abandoned mine sites. Surface ET covers have been used to manage the subsurface hydrology above landfills, waste sites, and mine lands. ET covers protect the underlying materials against erosion, provide a medium for vegetation growth, store precipitation within the cover, and release the stored water into atmosphere so that the infiltration of precipitation is minimized. A conceptual design study is carried out based on an actual, typical abandoned mine site near Raton, New Mexico, to which common problem conditions at abandoned mine sites are assumed. The purpose of this study is to present the concept that covers can be designed by integrating two remediation technologies (geomorphic grading and ET cover) as a geomorphic ET (GET) cover to improve performance. The overall shape of the GET cover can mimic the natural topography of the surrounding area, while the thickness and layering of the cover can be optimized for best vegetation growth and infiltration control. The application of GET cover technology on mine land is expected to substantially improve the reclamation effects by coupling the benefits of the geomorphic cover (drainage reduction, runoff management, vegetation diversity) with the benefits of ET covers (vegetation growth and sustainability, percolation reduction, protection of surface and groundwater). Additional

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The Evolution of Evapotranspiration Cover Systems at Barrick Goldstrike Mines

Cited by 7 publications

References 3 publications

Design of Inclined Covers with Capillary Barrier Effect by S.-E. Parent and A. Cabral

Design of Inclined Covers with Capillary Barrier Effect by S.-E. Parent and A. Cabral

Assessment of the Design of an Experimental Cover with Capillary Barrier Effect Using 4 Years of Field Data

Conceptual Model for Hydrology-Based Geomorphic Evapotranspiration Covers for Reclamation of Mine Land

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