Graphene/chitosan nanoreactors for ultrafast and precise recovery and catalytic conversion of gold from electronic waste
成果类型:
Article
署名作者:
Yang, Kou; Nikolaev, Konstantin G.; Li, Xiaolai; Ivanov, Artemii; Bong, Jia Hui; Erofeev, Ivan; Mirsaidov, Utkur M.; Kravets, Vasyl G.; Grigorenko, Alexander N.; Zhang, Shanqing; Qiu, Xueqing; Novoselov, Kostya S.; V. Andreeva, Daria
署名单位:
National University of Singapore; Institute for Functional Intelligent Materials (I-FIM); Guangdong University of Technology; National University of Singapore; National University of Singapore; National University of Singapore; National University of Singapore; University of Manchester
刊物名称:
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
ISSN/ISSBN:
0027-10200
DOI:
10.1073/pnas.2414449121
发表日期:
2024-10-15
关键词:
selective recovery
aqueous-solutions
graphene oxide
metal ions
adsorption
nanoparticles
reduction
chitosan
au(iii)
composites
摘要:
The extraction of gold (Au) from electronic waste (e- waste) has both environmental impact and inherent value. Improper e- waste disposal poses environmental and health risks, entailing substantial remediation and healthcare costs. Large efforts are applied for the recovery of Au from e- waste using complex processes which include the dissolution of Au, its adsorption in an ionic state and succeeding reduction to metallic Au. These processes themselves being complex and utilizing harsh chemicals contribute to the environmental impact of e- waste. Here, we present an approach for the simultaneous recovery and reduction of Au3+ and Au+ ions from e- waste to produce solid Au0 forms, thus skipping several technological steps. We develop a nanoscale cross- dimensional composite material via self- assembly of two- dimensional graphene oxide and one- dimensional chitosan macromolecules, capable of acting simultaneously as a scavenger of gold ions and as a reducing agent. Such multidimensional architecture doesn't require to apply any voltage for Au adsorption and reduction and solely relies on the chemisorption kinetics of Au ions in the heterogeneous GO/CS nanoconfinements and their chemical reduction on multiple binding sites. The cooperative phenomena in ionic absorption are responsible for the extremely high efficiency of gold extraction. The extraction capacity reaches 16.8 g/g for Au3+ and 6.2 g/g for Au+, which is ten times larger than any existing gold adsorbents can propose. The efficiency is above 99.5 wt.% (current limit is 75 wt.%) and extraction ability is down to very low concentrations of 3 ppm.