Upcycling Nickel Ions into self-supported Electrocatalyst by using ZIF-8/Bacterial cellulose adsorbent

IF 11.2 1区环境科学与生态学 Q1 ENGINEERING, ENVIRONMENTAL

Resources Conservation and Recycling Pub Date : 2024-09-06 DOI:10.1016/j.resconrec.2024.107890

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引用次数: 0

Abstract

Upcycling valuable metals from wastewater promises addressing the metal resource recycling and water pollution control issues simultaneously. In particular, upcycling Nickel (Ni) ions into electrocatalytic material has been proven a feasible route, but the current methods are still restricted by the complicated, environmentally-aggressive operation. Herein, we propose a low-cost, 3D-structured adsorbent, constructed by in-situ growing ZIF-8 on network-structured bacterial cellulose, for efficient Ni capture. It exhibits superior stability and 7.3-times higher Ni adsorption kinetics than the ZIF-8 alone. Importantly, the Ni-enriched adsorbent, after treatment of Ni-containing electroplating wastewater, could be pyrolytically converted into an efficient self-supported electrocatalyst for oxygen evolution reaction (OER), showing comparable OER activity to the state-of-the-art Ni-based electrode. This work provides a sustainable, facile route for Ni upcycling into self-supported electrode, which may be extended to recovery of various valuable metals from waste streams.

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利用 ZIF-8/细菌纤维素吸附剂将镍离子循环利用为自支撑电催化剂

从废水中回收有价值的金属有望同时解决金属资源回收和水污染控制问题。特别是，将镍（Ni）离子上升循环到电催化材料中已被证明是一条可行的途径，但目前的方法仍受到复杂、环境侵蚀性操作的限制。在此，我们提出了一种低成本、三维结构的吸附剂，它是通过在网络结构的细菌纤维素上原位生长 ZIF-8 而构建的，用于高效捕获镍。与单独的 ZIF-8 相比，它表现出卓越的稳定性和 7.3 倍的镍吸附动力学。重要的是，这种富含镍的吸附剂在处理含镍的电镀废水后，可以热解转化为高效的氧进化反应（OER）自支撑电催化剂，其 OER 活性与最先进的镍基电极相当。这项工作提供了一条可持续的、简便的将镍提升循环利用到自支撑电极的途径，该途径可扩展到从废物流中回收各种有价金属。

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来源期刊

Resources Conservation and Recycling 环境科学-工程：环境

CiteScore

22.90

自引率

6.10%

发文量

625

审稿时长

23 days

期刊介绍： The journal Resources, Conservation & Recycling welcomes contributions from research, which consider sustainable management and conservation of resources. The journal prioritizes understanding the transformation processes crucial for transitioning toward more sustainable production and consumption systems. It highlights technological, economic, institutional, and policy aspects related to specific resource management practices such as conservation, recycling, and resource substitution, as well as broader strategies like improving resource productivity and restructuring production and consumption patterns. Contributions may address regional, national, or international scales and can range from individual resources or technologies to entire sectors or systems. Authors are encouraged to explore scientific and methodological issues alongside practical, environmental, and economic implications. However, manuscripts focusing solely on laboratory experiments without discussing their broader implications will not be considered for publication in the journal.