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PbO 2 reductive dissolution by dissolved Mn(III) in the presence of low molecular weight organic acids and humic acid.

Mismel Ruiz-GarciaMark RichardsGiovanna Ballerini Ribeiro GomesVasileios Anagnostopoulos
Published in: Environmental science and pollution research international (2024)
Although Mn(III) complexes with organic ligands have been previously identified, the information about their stability and reactivity is scarce. In the present study, we analyzed the formation and stability of three different complexes: Mn(III)-citrate, Mn(III)-tartrate, and Mn(III)-humic acid (HA), as well as their reactivity toward an element of high environmental concern, lead (Pb).Our results indicate that the stability of studied complexes is highly dependent on pH. The Mn(III) complexes with citrate and tartrate degrade below pH 8, due to the electron transfer reaction between Mn(III) and the ligand, while the Mn(III)-HA complex's degradation is slower and less sensitive to pH. At pH 4, less than 40% of the initial Mn(III)-HA was found to be stable.The reactivity of the complexes was different depending on the ligand and its concentration. The Mn(III)-citrate and Mn(III)-tartrate complexes effectively reduced PbO 2 and releases aqueous Pb 2+ , although significant differences were found with increasing ligand concentration. There was no evidence of the reduction of PbO 2 by Mn(III) when it forms a complex with HA. This is likely due to the large size of HA moieties that prevent the Mn(III) component of the complex from getting close enough to the PbO 2 surface to initiate electron transfer and lead to the reduction of Pb(IV) by HA itself.
Keyphrases
  • room temperature
  • transition metal
  • metal organic framework
  • electron transfer
  • heavy metals
  • risk assessment
  • climate change
  • human health