Modelling a pit lake district to plan for abstraction regime changes

McCullough, Cherie D.; Müller, Mike; Eulitz, Katja; Lund, Mark A.

doi:10.36487/acg_rep/1152_61b_mccullough

Cited by 4 publications

(1 citation statement)

References 13 publications

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“…shows bathymetry data for Lake Stockton collected byMcCullough et al (2011). Physical dimensions of Lake Stockton are outlined inTable 1.…”

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confidence: 99%

Modelling the long-term water balance of a pit lake with recreational end uses

Carlino¹,

McCullough²

2019

Proceedings of the International Conference on Mine Closure

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Pit lakes can be used for recreation when water quality is suitable. However, when lake levels are too low, pit lakes may pose access and slope instability risks to recreational users. An essential tool to assist in managing these risks is a good understanding of the lake water balance. A groundwater model was developed to investigate whether impending cessation of mine water discharge into historic Lake Stockton (Collie, Western Australia) would result in reduced recreational values, e.g. for water skiing. Currently, the lake water level is kept reasonably constantly elevated with the addition of mine water from nearby dewatering at Ewington mine (Lanco, Griffin Coal) operations. Lake Stockton has a maximum depth of 30 m and groundwater flows through historic underground mine workings contribute largely to the overall pit inflow. A steady state groundwater model was used to emulate the regional groundwater flow in the Collie Coal Basin. The model gave estimates of groundwater fluxes and predictions of the future lake water level if mine discharges were to stop. Transient simulations forecast a 3.6-3.9 m decline in the long-term lake water level without mine water input, with non-mine groundwater inflow rates increasing from commensurately steeper hydraulic gradient from a declining lake level in steady state. As a result, although the water level of Lake Stockton would still be suitable for public recreation, the decline in the water level would expose steep pit walls and reduce the regulation recreational area by 17%. Consequently, rehabilitation planning for this lake should account for safe access if recreation is to be permitted when the predicted decline in water levels takes place. The study highlights the critical importance of understanding the hydrogeological setting and the controls over lake levels in-pit voids for maintenance of recreational end use values.

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“…shows bathymetry data for Lake Stockton collected byMcCullough et al (2011). Physical dimensions of Lake Stockton are outlined inTable 1.…”

mentioning

confidence: 99%

Modelling the long-term water balance of a pit lake with recreational end uses

Carlino¹,

McCullough²

2019

Proceedings of the International Conference on Mine Closure

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Quantifying Iron Concentration in Local and Synthetic Acid Mine Drainage: A New Technique Using Handheld Field Spectrometers

Davies

Calvin

2016

Mine Water Environ

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Pit lakes present a concern for public safety and environmental quality. With continuing advancement of imaging satellites, remote sensing spectroscopy may provide a useful tool for monitoring pit water quality across vast mining districts. Visible to shortwave infrared remote sensing has been widely used to monitor acid mine drainage (AMD) mineralogy at mine sites. However, few studies have examined the spectral signatures of mine-affected waters and open pit water bodies from a remote platform. The motivation for this study was to identify the spectral characteristics of AMD in a controlled laboratory setting in order to better interpret mine water bodies in remote sensing imagery. The spectral response of synthetic and local AMD were measured using a field spectrometer. Solutions with increasing Fe 3? and Fe 2? concentrations were mixed to mimic the chemical properties of local AMD. Synthetic solutions with known Fe concentrations were compared with local AMD for quantitative assessment. The spectral signatures of Fe 3? dominated waters possessed distinct characteristics that may be used for diagnostic identification. Specifically, the region between 0.35 and 0.625 lm was used to approximately quantify Fe 3? concentrations. Subtle changes in Fe concentrations in local AMD were identified using a field spectrometer alone. These findings suggest that subtle changes in open pit water quality may also be qualitatively and quantitatively measured by remote sensing spectroscopy.

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Studying Mine Pit Lake Systems Across Multiple Scales

McCullough¹,

Vandenberg²

2020

Mine Water Environ

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Modelling a pit lake district to plan for abstraction regime changes

Cited by 4 publications

References 13 publications

Modelling the long-term water balance of a pit lake with recreational end uses

Modelling the long-term water balance of a pit lake with recreational end uses

Quantifying Iron Concentration in Local and Synthetic Acid Mine Drainage: A New Technique Using Handheld Field Spectrometers

Studying Mine Pit Lake Systems Across Multiple Scales

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