Synergistic function of iron and cobalt in metallic glasses for highly improving persulfate activation in water treatment

Although metallic glasses (MGs) with unique disordered atomic structure have increasingly attracted great research interest as one of the most innovative heterogeneous catalysts in water remediation, few works focused on the synergistic role of different elemental constituents to well understand the...

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Bibliographic Details
Published in:Journal of alloys and compounds 2020-05, Vol.822, p.153574, Article 153574
Main Authors: Jiang, J.L., Jia, Z., He, Q., Wang, Q., Lyu, F., Zhang, L.C., Liang, S.X., Kruzic, J.J., Lu, J.
Format: Article
Language:English
Subjects:
Activation
Amorphous materials
Amorphous structure
Atomic structure
Catalysts
Dyes
Heterogeneous catalysis
Iron constituents
Malachite green
Metallic glass
Metallic glasses
Methylene blue
Persulfate activation
Rhodamine
Synergistic function
Water treatment
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Summary:Although metallic glasses (MGs) with unique disordered atomic structure have increasingly attracted great research interest as one of the most innovative heterogeneous catalysts in water remediation, few works focused on the synergistic role of different elemental constituents to well understand their superb catalytic performance. Herein, Co atoms were selected to partially substitute for the Fe elements in Fe-based MGs to study the corresponding synergistic catalytic function in dye degradation. Experimental results demonstrated that the Fe36Co36Si4.8B19.2Nb4 MG with a kinetic rate constant of k = 0.06 min−1 degrades rhodamine B (RhB) dye 20 times faster than the Fe73.5Si13.5B9Cu1Nb3 MGs with k = 0.003 min−1. Three types of dye including RhB, methylene blue (MB) and malachite green were investigated to draw attention to the broad, practical applications. Various chemical parameters, such as catalyst dosage, persulfate concentration, and dye concentration, were also studied. Quenching experiments indicated that the highly active hydroxyl (⋅OH) and sulfate (SO4⋅−) radicals are largely produced from persulfate by the activation of the Fe36Co36Si4.8B19.2Nb4 MG catalyst. This critical work uncovers a new paradigm to establish an effective approach for alloy design in widespread catalytic applications. [Display omitted] •Co atoms were selected to partially substitute for the Fe elements in Fe-based MGs.•Catalytic activity was greatly enhanced by synergistic function of iron and cobalt.•Increasing boron contents could promote dye degradation efficiency.•⋅OH and SO4⋅− were found to be the primary radicals for dye degradation.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2019.153574