氧化还原介导的电化学液液萃取技术用于选择性金属回收

Stephen R. Cotty, Aderiyike Faniyan, Johannes Elbert, Xiao Su
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引用次数: 0

摘要

电化学分离是实现关键元素可持续回收、环境修复和下游加工的强大平台。然而,近年来电分离技术的发展主要集中在异质吸附剂上,这些吸附剂面临着间歇性电旋转操作的挑战。在这里,我们提出了一种氧化还原介导的电化学液-液萃取分离平台,将选择性单位结合转化为完全连续的分离方案。氧化还原活性萃取剂的分子设计具有可控的疏水性,能最大限度地保留有机相。氧化还原流设计实现了完全电气化的连续操作,无需外部化学输入,从而实现了从多组分流中选择性回收贵金属。我们展示了超过 90% 的原子效率和超过 100:1 的实用关键金属浸出流选择性,以及从不同原料(包括电子废料、催化转化器废料和采矿流)中提取黄金和铂族金属的 16 倍高浓度。根据设想,我们的研究工作将成为一条通往更广泛的工业适用液液萃取电化学分离技术的途径。从电子废料、催化转化器废料和采矿流等来源中回收金和铂族金属仍然具有挑战性。现在,电化学介导的液-液萃取工艺利用氧化还原活性萃取剂的选择性,从各种原料中选择性地回收包括金和铂族金属在内的贵金属和关键金属。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Redox-mediated electrochemical liquid–liquid extraction for selective metal recovery

Redox-mediated electrochemical liquid–liquid extraction for selective metal recovery
Electrochemical separations are powerful platforms for the sustainable recovery of critical elements, environmental remediation and downstream processing. However, the recent development of electroseparations has primarily focused on heterogeneous adsorbents, which face the challenge of intermittent electroswing operation. Here we present a redox-mediated electrochemical liquid–liquid extraction separation platform that translates selective single-site binding to a fully continuous separation scheme. A redox-active extractant is molecularly designed with controllable hydrophobicity to maximize organic phase retention. The redox flow design enables fully electrified continuous operation with no external chemical input, achieving the selective recovery of precious metals from multicomponent streams. We demonstrate an atomic efficiency of over 90% and over 100:1 selectivity for practical critical metal leach streams, and 16-fold up-concentration for gold and platinum group metals from varied feedstocks including electronic waste, catalytic converter waste and mining streams. Our work is envisioned as a pathway towards a broader class of industrially applicable liquid–liquid extraction-based electrochemical separations. The recovery of gold and platinum group metals from sources like electronic waste, catalytic converter waste and mining streams remains challenging. Now, an electrochemically mediated liquid–liquid extraction process leverages the selectivity of redox-active extractants for the selective recovery of precious and critical metals including gold and platinum group metals from diverse feedstocks.
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