Abstract
The fixation and accumulation of critical elements in the near surface environment is an important factor in understanding elemental cycling through the crust, both for exploration of new resources and environmental management strategies. Carbonaceous black shales are commonly rich in trace elements relative to global crustal averages, many of which have potential environmental impacts depending on their speciation and mobility at surface. This trace element mobility can be investigated by studying the secondary mineralisation (regolith) associated with black shales at surface. In this study, Carboniferous shales on the west coast of Ireland are found to have higher than average shale concentrations of As, Cd, Cu, Co, Mo, Ni, Se, Te and U, similar to the laterally equivalent Bowland Shales, UK. Groundwater penetration and oxidative weathering of these pyritic black shales produces oxide deposits, dominated by goethite and jarosite, which are significantly enriched in As (44–468 ppm), Se (12–184 ppm), U (6–158 ppm) and other trace elements, compared to concentrations in the parent shales. Major elemental abundances vary in composition from 3.5 to 29.4% sulphate, 0.6–9.1% phosphate and 36.6–47.2% iron-oxide. Phosphate substitution within jarosite is observed in these samples, formed under ambient pressure and temperature conditions.The major and trace elements forming these secondary deposits are predominantly sourced from the underlying black shales through mobilisation by groundwater. This discovery is critical for the environmental assessment of black shale lithologies during shale gas exploration and production, where the demonstrated mobility of in situ elemental enrichments may indicate a significant source of produced- and groundwater contamination during and after hydraulic fracturing processes. The proportions of the major oxide phases exhibit a clear control on the trace elemental enrichments within the secondary deposits, where increasing Se and As concentrations correlate with increasing phosphate content of the jarosite mineralisation. This has implications for the remediation of acid mine drainage seeps, where phosphate-rich jarosite phases could be utilised for more efficient trace element removal.
Highlights
Carbonaceous sedimentary rocks are commonly enriched in redox sensitive trace elements, relative to average crustal abundances (Hu and Gao, 2008; Turekian and Wedepohl, 1961), including selenium (Se), arsenic (As), molybdenum (Mo), uranium (U), copper (Cu) and tellurium (Te)
Average shale and upper crustal concentrations for the elements are given, with ratios calculated for Irish Carboniferous Shale/ Average Shale and Regolith/Upper Crustal Average
We suggested that during hydraulic fracturing processes, both nearby groundwater and produced waters could become contaminated through the chemical weathering of black shale formations and subsequent leaching of trace elements
Summary
Carbonaceous sedimentary rocks are commonly enriched in redox sensitive trace elements, relative to average crustal abundances (Hu and Gao, 2008; Turekian and Wedepohl, 1961), including selenium (Se), arsenic (As), molybdenum (Mo), uranium (U), copper (Cu) and tellurium (Te). These elements are either of environmental concern, or economic importance, with Se, As, Mo and U considered environmentally hazardous in elevated concentrations (Bajwa et al, 2017; Hakonson-Hayes et al, 2002; Zheng et al, 1999) and Cu, Te, Se and Mo of increasing economic value in modern technologies (Cucchiella et al, 2015). Identifying new sites of crustal enrichment for these elements is key in targeted exploration and securing adequate future supply of critical metals
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