Ultra-rapid synthesis of the MgCu2 and Mg2Cu Laves phases and their facile conversion to nanostructured copper with controllable porosity; an energy-efficient, reversible process

Phase-pure MgCu2 and high-purity Mg2Cu have been synthesised within 1 min from elemental powders via the microwave-induced metal plasma (MIMP) approach for the first time. Subsequent room temperature, acidic de-alloying led to 3-dimensional nanoporous (NP) Cu within minutes. Each distinctive metalli...

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Bibliographic Details
Published in:Green chemistry : an international journal and green chemistry resource : GC 2021-09, Vol.23 (18), p.6936-6944
Main Authors: Fan, Zhen, Baranovas, Gytis, Yu, Holly A, Szczęsny, Robert, Wei-Ren, Liu, Gregory, Duncan H
Format: Article
Language:English
Subjects:
Chemoreception
Confidence intervals
Copper
Copper converters
Crystal defects
Energy efficiency
Green chemistry
Heavy metals
Information processing
Laves phase
Ligaments
Metallic plasmas
Porosity
Room temperature
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Summary:Phase-pure MgCu2 and high-purity Mg2Cu have been synthesised within 1 min from elemental powders via the microwave-induced metal plasma (MIMP) approach for the first time. Subsequent room temperature, acidic de-alloying led to 3-dimensional nanoporous (NP) Cu within minutes. Each distinctive metallic matrix exhibited a large surface area with a porosity of either 37.47% (from MgCu2) or 56.25% (from Mg2Cu). Both NP Cu powders are composed of crystalline grains (“ligaments”) measuring tens of nanometers across, which exhibit rich point- and extended defects. The selection of Laves precursor dictates the form of ligament obtained, which directs the ensuing NP structure. Working electrodes of both types of NP Cu presented reliable linear non-enzymatic sensing properties over glucose concentrations of 0.5–4.5 and 4.5–10.0 mM with high confidence levels (>99%). This study provides a facile, rapid and energy-efficient route to functional NP Cu with eclectic structures, which should be equally applicable to other metals.
ISSN:1463-9262
1463-9270
DOI:10.1039/d1gc01710a