Bone char switch on reductive dehalogenation of trichloroethene by series of Fe(II)-bearing minerals: The balance between kinetics and electron efficiency.

[Display omitted] • Fe(II)-bearing minerals alone are non-reactive to trichloroethylene reduction. • Fe(II)-bone char could effectively reduce trichloroethylene to acetylene. • The Fe(II)-bone char were prepared by simple mixing in water. • Fast kinetics did not guarantee high electron efficiency. • Suitable crystallinity of Fe(II) enable steady and long lasting TCE reduction. Fe(II)-bearing minerals might be able to drive the attenuation of chlorinated ethene in soil and groundwater, however, with relatively slow kinetics. In this study, bone char(BC) was selected as an efficient and benign catalyst to prepare composites with three different Fe(II)-bearing minerals (Green rust (GR), Fe(OH) 2 and FeS), respectively, for enhanced trichloroethylene (TCE) dehalogenation. The kinetics experiment demonstrated that the presence of BC could effectively switch on the TCE dehalogenation by these solids, while these Fe(II)-bearing minerals alone can barely reduce any TCE. Surprisingly, the Fe(OH) 2 -BC showed fastest TCE reduction rate, followed by GR-BC and FeS-BC in sequence. Acetylene was confirmed as the major dehalogenation products while other chlorinated byproducts were hardly detected. The electron efficiency (η e) for TCE reduction was further calculated and compared among these BC amended systems, the results show that the highest η e value was recorded in GR-BC system as 33.14% with high loading of TCE. Solid phase characterization confirmed that the high loading of amorphous Fe(II) on the BC surface might effectively improve the TCE dehalogenation kinetics, while the well crystallized Fe(II)-bearing minerals would increase the electron efficiency. According to this mechanism, it might be possible to achieve balance between kinetics and electron efficiency. Stress resistance test in real groundwater matrix and life cycle analysis (LCA) was conducted to further verify the application potential of these composites. [ABSTRACT FROM AUTHOR]