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Acid Mine Drainage Remediation: Aluminum Chelation Using Functional Graphenic Materials.

Michelle M KarpinskyAnne M ArnoldJaejun LeeGenell JasperMichael R BockstallerStefanie A SydlikEdward P Zovinka
Published in: ACS applied materials & interfaces (2020)
Acid mine drainage (AMD) is a pervasive source of metal pollution that severely impacts freshwater ecosystems and has a direct impact on human health. Conventional active and passive methods work very well for removing iron in AMD remediation, which is typically the highest metallic impurity. However, conventional passive remediation fails to remove all aluminum, which has severe ecological implications. Removal of aluminum ions using chelation, which traditionally uses small molecules that bind metals tightly for sequestration, holds promise. Yet, chelation strategies are limited because once introduced into surface water, small molecules are difficult to reclaim and often persist in the environment as pollutants. To address this, we have designed six unique scaffolds based on functional graphenic materials (FGMs) to create nonsoluble materials that could be placed at the end of a passive remediation process to remove persistent aluminum. When tested for efficacy, all six FGMs successfully demonstrated a reversible capacity to remove aluminum from acidic water, chelating up to 21 μg of Al/mg of FGM. Furthermore, when they were exposed to E. coli as an approximation for environmental compatibility, viability was unaffected, even at high concentrations, suggesting these FGMs are nontoxic and viable candidates for passive chelation-based remediation.
Keyphrases
  • human health
  • risk assessment
  • climate change
  • heavy metals
  • escherichia coli
  • ultrasound guided
  • health risk assessment
  • ionic liquid
  • big data
  • life cycle