Abstract
In light of the consequences of global warming and population growth, access to safe drinking water becomes an ever greater challenge, in particular in low to middle income countries in arid regions. Moreover, mining which may cause acid mine drainage and heavy metal contamination puts further pressure on management of limited water resources. Hence, the development of cost effective water treatment methods is critical. Here, using batch reactor experiments we investigate the kinetics and mechanisms behind divalent Mn and trivalent Cr removal from sulfate fluids using natural fluorapatite at 35 °C. The results show that the fluorapatite dissolution rate depends on fluid pH, and that dissolution is the dominant mechanism in fluids with pH below 4. Apatite can thus serve as remediation to neutralize acidic fluids. Fluid pH of 4–6 triggers a dissolution-precipitation mechanism, in some cases following upon a dissolution-only period, with the formation of a metal phosphate. In these experiments, Cr removal is two to ten times faster than Mn removal given similar solution pH. The results demonstrate that natural apatite represents a promising, cost effective material for use in passive remediation of mining-induced contamination of soils and groundwater in arid regions.
Highlights
One of the biggest challenges humankind is currently facing is the access to safe drinking water and food supply
The fluorapatite structure is confirmed by the nuclear magnetic resonance (NMR) spectrum (Fig. 2)
This interpretation is based on previous NMR research on fluorohydroxyapatites [Ca5(PO4)3(F,OH)] which suggested that the relative intensities for Ca(I) and Ca(II) peaks vary as a function of F― content (Chen et al, 2015)
Summary
One of the biggest challenges humankind is currently facing is the access to safe drinking water and food supply This challenge is amplified by the growth in population, and by the consequences of climate change. The Golden Triangle Area has very limited surface water, and the industrial and agricultural development in this area relies on groundwater, which is the source for drinking water (Amer et al, 2012). This area will need a viable development of sustainable water resources and water management. Mining development and the interrelated need for water management and treatment for reuse is relevant and critical in many arid and semi-arid regions
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