Title of article
Biological manganese removal from acid mine drainage in constructed wetlands and prototype bioreactors
Author/Authors
Kevin B. Hallberg، نويسنده , , D. Barrie Johnson*، نويسنده ,
Issue Information
هفته نامه با شماره پیاپی سال 2005
Pages
10
From page
115
To page
124
Abstract
Mine drainage waters vary considerably in the range and concentration of heavy metals they contain. Besides iron,
manganese is frequently present at elevated concentrations in waters draining both coal and metal mines. Passive treatment
systems (aerobic wetlands and compost bioreactors) are designed to remove iron by biologically induced oxidation/
precipitation. Manganese, however, is problematic as it does not readily form sulfidic minerals and requires elevated pH (N8) for
abiotic oxidation of Mn (II) to insoluble Mn (IV). As a result, manganese removal in passive remediation systems is often less
effective than removal of iron. This was found to be the case at the pilot passive treatment plant (PPTP) constructed to treat
water draining the former Wheal Jane tin mine in Cornwall, UK, where effective removal of manganese occurred only in one of
the three rock filter components of the composite systems over a 1-year period of monitoring. Water in the two rock filter
systems where manganese removal was relatively poor was generally bpH 5, whereas it was significantly higher (~pH 7) in the
third (effective) system. These differences in water chemistry and manganese removal were due to variable performances in the
compost bioreactors that feed the rock filter units in the composite passive systems at Wheal Jane. An alternative approach for
removing soluble manganese from mine waters, using fixed bed bioreactors, was developed. Ferromanganese nodules (about 2
cm diameter), collected from an abandoned mine adit in north Wales, were used to inoculate the bioreactors (working volume
ca. 700 ml). Following colonization by manganese-oxidizing microbes, the aerated bioreactor catalysed the removal of soluble
manganese, via oxidation of Mn (II) and precipitation of the resultant Mn (IV) in the bioreactor, in synthetic media and mine
water from the Wheal Jane PPTP. Such an approach has potential application for removing soluble Mn from mine streams and
other Mn-contaminated water courses.
Keywords
Acid mine drainage , Bioremediation , bioreactors , manganese , Manganese-oxidizing bacteria , Wetland , Wheal Jane
Journal title
Science of the Total Environment
Serial Year
2005
Journal title
Science of the Total Environment
Record number
983981
Link To Document