Ultrasonic-prepared porous CuGa2 alloy for efficiently removing undesired room-temperature liquid metals from various substrates

Ultrasonic-prepared porous CuGa2 alloy for efficiently removing undesired room-temperature liquid metals from various substrates

An efficient and reusable ‘sponge’ based on a porous CuGa _2 alloy (PCA) is developed for removing excess or unwanted room-temperature liquid metals (RTLMs), such as Ga and its room-temperature alloys, from various substrates. PCA is easily prepared using an ultrasonic-enhanced wet/alloy strategy, w...

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Bibliographic Details
Main Authors: Xu Bi, Xiaotong Guo, Miao Sun, Shuyue Tan, Wencheng Song, Hao Liu, Dandan Shi, Shutao Wen, Haitao Li, Han Dai
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:Materials Research Express
Subjects:
room temperature liquid metal
porous CuGa2 alloy
capillary adsorption
flexible electronics
Online Access:https://doi.org/10.1088/2053-1591/adcf7c
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Summary:An efficient and reusable ‘sponge’ based on a porous CuGa _2 alloy (PCA) is developed for removing excess or unwanted room-temperature liquid metals (RTLMs), such as Ga and its room-temperature alloys, from various substrates. PCA is easily prepared using an ultrasonic-enhanced wet/alloy strategy, where Ga penetrates and reacts with the copper foam substrate. The RTLM absorption is highly correlated with the pore density and volume of hydrochloric acid in the PCA. By regulating the pore density and volume of hydrochloric acid, PCA exhibits high RTLM removal efficiencies on different material surfaces, namely wood, nitrile gloves, plastic, and glass. For PCA (1.5 cm × 1.0 cm × 0.3 cm) with 300 pores per linear inch and 40 μl of hydrochloric acid, the strongest liquid Ga adsorption capacity is observed, and the maximum weight gain reaches approximately 352 ± 4% after absorption. The high removal efficiency of PCA is attributed to its high wettability with RTLM and high capillary adsorption capacity. Furthermore, PCA is very economical; it can be recycled and reused without losing its RTLM adsorption capacity or mechanical strength. Herein, the convenience of using PCA is demonstrated in LED circuit editing, highlighting its potential in flexible electronics applications.
ISSN:2053-1591

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