Comparison of selected washing treatments onAgrostis gigantea samples from mine tailings near Copper Cliff,Ontario, before analysis for Cu,Ni, Fe and K content

Summary Plants ofAgrostis gigantea Roth collected from Cu/Ni tailings near Copper Cliff, Ontario, were contaminated by substrate particles, and also on roots by an iron hydroxide plaque. Three washing treatments were compared on shoots and six on roots, prior to analysis for Cu, Ni and Fe. K content was compared to detect leaching. For both shoots and roots, rinsing with de-ionized water was as effective as Extran-300 or ultrasound. These three treatments caused no measured leaching from shoots. DCB removed iron plaque from roots; hot or cold EDTA removed some plaque. All treatments caused leaching of K from roots.     

Sustainable natural remediation of abandoned tailings by metal-excluding heather (Calluna vulgaris) and gorse (Ulex europaeus), Carnon Valley, Cornwall, UK

This study was conducted to determine the uptake of elements (Ag, Al, As, Ca, Cd, Co, Cu, Fe, Mn, Mo, Ni, Pb, P, S, Sb, Tl, U, W, Zn) by native gorse (Ulex europaeus) and heather (Calluna vulgaris), growing on abandoned tailings, Carnon Valley, Cornwall, UK. The metalliferous tailings are particularly As-rich (0.11-0.59 wt% As) and contain acid-generating sulfides (pH 3.36-6.59). Since abandonment three decades ago, gorse and heather have colonized much of the exposed tailings surface. Biogeochemical analyses demonstrate that gorse and heather are opportunistic, pioneering metallophytes that have the ability to exclude metals and As from their above-ground biomass. Concentrations of trace elements in gorse and heather were evaluated in terms of maximum tolerable levels in the feed of rodents and horses. The analyses revealed that gorse and heather do not accumulate large quantities of trace elements (Al, As, Cd, Co, Cu, Ni, Pb, Zn) in their tissue, preventing harmful effects on rabbits feeding on them and transfers of trace metals and As into the developing wildlife food chains. This study demonstrates that (a) biogeochemical examinations of abandoned mined lands can reveal pioneering, metal-excluding plants; and (b) abandonment and benevolent neglect of mined lands can lead to the successful development of sustainable vegetation covers over mine wastes in the long term.     

Bacterial formation of struvite

We studied the formation of exocellular precipitates of struvite (Mg NH₄PO4.6H₂O) by 96 kinds of calcite‐pro‐ducing bacterial strains isolated from soil. We also studied the influence of calcium ions on struvite precipitation. The number of strains producing struvite was 20. Only four consistently formed large amounts. These results seem to indicate that the bacterial precipitation of struvite is not a general phenomenon. The strains studied were taxonomically identified, and no relationship was found between the production of struvite and the taxonomic identity of such strains. Calcium, supplied as Ca acetate in the culture medium, appeared to inhibit the biological precipitation of struvite.     

Sustainability in metal mining: from exploration, over processing to mine waste management

Metal mining or more general mineral mining, is the base industry of the economic wealth and development of numerous countries. However, mining has a negative reputation due to the complex problems of environmental contamination like SO₂ and CO₂ emissions and acid mine drainage (AMD) formation, which endangers vital limited resources, like air, water, and soils. This view paper highlights the environmental problems of todays metal mining operations and explores possibilities of future more sustainable mining operations with focus on enhanced and optimized metal recovery systems in combination with a minimization of the environmental impact. These changes depend on a change in mentality and in the mining operation process, which can nowadays yet be observed in some modern mining operations. The goal for the future will be to implement these changes as standard for all future mining operations.     

Introduction

Biosorption of aluminum by sulfate-reducing bacteria isolated from uranium mine tailings was examined. A top agar method with Alizarin Red S was used for initial screening of the isolates for aluminum tolerance and biosorption. Five strains of aluminumion-fixing sulfate-reducing bacteria and a strain designated UFZ B 406 isolated from another source were used in the experiments. The mechanism of aluminum biosorption was found to be a passive one. Freezing and thawing of the cells resulted in higher sorption of aluminum, whereas heat treatment or the uncoupler carbonyl-cyanide-m- chlorophenylhydrazone (CCCP) had no effect. The pH value had significant influence on the aluminum ion adsorption, the most absorbance being at pH 3 and 5, and the lowest at pH 7. Addition of magnesium and the presence of iron sulfide precipitates decreased aluminum sorption. The relationship between biomass and Al3+ ions accumulated was linear. Polyphosphate granules as possible site of aluminum accumulation were not found to be present. Fluorescence microscopy showed deposition of aluminum ions exclusively on the surface of the cell. Use of the isolates in bioremediation processes for removing aluminum from water is considered.