H. Wang scite author profile

In addition to its scientific importance, the degradation of azo dyes is of practical significance from the perspective of environmental protection. Although encouraging progress has been made on developing degradation approaches and materials, it is still challenging to fully resolve this long-standing problem. Herein, we report that high entropy alloys, which have been emerging as a new class of metallic materials in the last decade, have excellent performance in degradation of azo dyes. In particular, the newly developed AlCoCrTiZn high-entropy alloy synthesized by mechanical alloying exhibits a prominent efficiency in degradation of the azo dye (Direct Blue 6: DB6), as high as that of the best metallic glass reported so far. The newly developed AlCoCrTiZn HEA powder has low activation energy barrier, i.e., 30 kJ/mol, for the degrading reaction and thus make the occurrence of reaction easier as compared with other materials such as the glassy Fe-based powders. The excellent capability of our high-entropy alloys in degrading azo dye is attributed to their unique atomic structure with severe lattice distortion, chemical composition effect, residual stress and high specific surface area. Our findings have important implications in developing novel high-entropy alloys for functional applications as catalyst materials.

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High thermal stability and sluggish crystallization kinetics of high-entropy bulk metallic glasses

Yang

Liu

Ruan

et al. 2016

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Designing novel bulk metallic glass composites with a high aluminum content

Chen

Gao

et al. 2013

Sci Rep

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The long-standing challenge for forming Al-based BMGs and their matrix composites with a critical size larger than 1 mm have not been answered over the past three decades. In this paper, we reported formation of a series of BMG matrix composites which contain a high Al content up to 55 at.%. These composites can be cast at extraordinarily low cooling rates, compatible with maximum rod diameters of over a centimetre in copper mold casting. Our results indicate that proper additions of transition element Fe which have a positive heat of mixing with the main constituents La and Ce can appreciably improve the formability of the BMG matrix composites by suppressing the precipitation of Al(La,Ce) phase resulted from occurrence of the phase separation. However, the optimum content of Fe addition is strongly dependant on the total amount of the Al content in the Al-(CoCu)-(La,Ce) alloys.

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Fe-based bulk metallic glass composites without any metalloid elements

Gao

Chen

et al. 2013

Acta Materialia

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Nanocrystallization in a Cu-doped Fe-based metallic glass

Gao

et al. 2016

Journal of Alloys and Compounds

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Evolution of microstructure and magnetic properties during annealing of a Cudoped Fe 75.3 C 7.0 Si 3.3 B 5.0 P 8.7 Cu 0.7 metallic glass were investigated via atom probe tomography. Cu segregation, which contains a rapid nucleation stage and a sluggish growth stage, was found to precede and may trigger the segregation of other elements and promote the following nanocrystallization. The nano-sized α-Fe precipitates have a composition close to that of the grain-orientated high-silicon steel, giving rise to the enhancement in the magnetization.

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H. Wang

Development of a novel high-entropy alloy with eminent efficiency of degrading azo dye solutions

High thermal stability and sluggish crystallization kinetics of high-entropy bulk metallic glasses

Designing novel bulk metallic glass composites with a high aluminum content

Fe-based bulk metallic glass composites without any metalloid elements

Nanocrystallization in a Cu-doped Fe-based metallic glass

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