AI Article Synopsis
- The study details the creation of nanoporous Cu (NP-Cu) powders made from Zr-Cu-Ni-Al metallic glassy precursors, resulting in a unique three-dimensional porous structure.
- The NP-Cu powders demonstrated high efficiency in breaking down azo dyes in both acidic (pH 2) and neutral (pH 7) conditions, along with good durability in repeated tests.
- A new degradation mechanism suggests that in acidic environments, the catalyst generates hydroxyl radicals through a specific reaction pathway, while in neutral conditions, it operates through a classical Fenton-like process to achieve the same result.
Article Abstract
The catalyst of nanoporous Cu (NP-Cu) powders, with the chemical composition of CuNiO(at%), was successfully fabricated by dealloying of Zr-Cu-Ni-Al metallic glassy precursors. The as-prepared NP-Cu powders, co-existing with CuO phase on Cu ligament surface, had a three-dimensional network porous structure. The NP-Cu powders/HOsystem showed superior catalytic degradation efficiency toward azo dyes in both acidic (pH 2) and neutral (pH 7) environments. Moreover, the cyclic tests indicated that this powder catalyst also exhibited good durability. A novel degradation mechanism of NP-Cu powders/HOwas proposed: the high degradation performance in acidic environment was mainly derived from heterogeneous reaction involved with a specific pathway related to Cuto produce HO·, while in neutral environment it was primarily resulted from homogeneous reaction with the generation of HO· from the classical Cu-based Fenton-like process. This work indicates that the NP-Cu powders have great potential applications as catalysts for wastewater treatments.
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| http://dx.doi.org/10.1088/1361-6528/ac3bec | DOI Listing |
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Article Synopsis
- The study details the creation of nanoporous Cu (NP-Cu) powders made from Zr-Cu-Ni-Al metallic glassy precursors, resulting in a unique three-dimensional porous structure.
- The NP-Cu powders demonstrated high efficiency in breaking down azo dyes in both acidic (pH 2) and neutral (pH 7) conditions, along with good durability in repeated tests.
- A new degradation mechanism suggests that in acidic environments, the catalyst generates hydroxyl radicals through a specific reaction pathway, while in neutral conditions, it operates through a classical Fenton-like process to achieve the same result.
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