合成共锌铝层双氢氧化物，以有效活化过一硫酸盐，从而降解污染水中的罗丹明 B 和甲基橙

IF 3.6 4区工程技术 Q3 ENERGY & FUELS

Energy technology Pub Date : 2024-08-29 DOI:10.1002/ente.202401293

Hafiza Mehwish Rasheed, Chunsheng Ding, Minghua Xu, Bilal Zaman, Xiaowen Ruan, Xiaoqiang Cui

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引用次数: 0

摘要

基于硫酸根高级氧化过程的创新技术在降解不纯净水中的染料方面受到越来越多的关注。本文在组装 LDH 的基础上合成了掺钴锌铝层状双氢氧化物（LDH）催化剂，用于高效活化过一硫酸盐并同时催化降解罗丹明 B（RhB）和甲基橙（MO）。金属钴被加入到 ZnAl-LDH 晶格中，以加速 ZnAl-LDH 的催化性能。实验结果表明，Co-ZnAl-LDH（Co = 0.05 mmol）体系通过活性氧的攻击和电子转移过程，对 RhB 和 MO 的降解效果显著，最大降解效率分别为 98.97% 和 98.04%。此外，该催化剂的结构稳定性和催化性能使其在实际水处理中大有可为，并提高了其再利用能力。

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Synthesis of Co–ZnAl‐Layered Double Hydroxide for Effective Activation of Peroxymonosulfate to Degrade Rhodamine B and Methyl Orange from Polluted Water

Innovative technologies based on the sulfate radical advanced oxidation process are attracting more attention for the degradation of dyes in impure water. Herein, cobalt‐doped zinc aluminum layered double hydroxide (LDH) catalysts are synthesized based on the assembly of LDHs for efficient activation of peroxymonosulfate and simultaneous catalytic degradation of rhodamine B (RhB) and methyl orange (MO). Cobalt metal is incorporated into the ZnAl‐LDH lattice to accelerate the catalytic performance of ZnAl‐LDHs. The experimental results show that the Co–ZnAl‐LDH (Co = 0.05 mmol) system demonstrates remarkable degradation of RhB and MO with maximum degradation efficiencies of 98.97% and 98.04%, respectively, through the attack of reactive oxygen species and electron transfer processes. Furthermore, the structural stability and catalytic performance of the catalyst make it promising for practical water treatment as well as promoting its reuse ability.

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来源期刊

Energy technology ENERGY & FUELS-

CiteScore

7.00

自引率

5.30%

发文量

审稿时长

1.3 months

期刊介绍： Energy Technology provides a forum for researchers and engineers from all relevant disciplines concerned with the generation, conversion, storage, and distribution of energy. This new journal shall publish articles covering all technical aspects of energy process engineering from different perspectives, e.g., new concepts of energy generation and conversion; design, operation, control, and optimization of processes for energy generation (e.g., carbon capture) and conversion of energy carriers; improvement of existing processes; combination of single components to systems for energy generation; design of systems for energy storage; production processes of fuels, e.g., hydrogen, electricity, petroleum, biobased fuels; concepts and design of devices for energy distribution.