Catalytic reduction of SO2 by Gd@CeOx catalysts: stability enhancement and structural modulation

IF 5.8 2区环境科学与生态学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Environmental Science: Nano Pub Date : 2025-01-16 DOI:10.1039/d4en01156b

Mutao Xu, Xinpei Cheng, Liguo Chen, Qijie Jin, Jian Yang, Jing Song, Changcheng Zhou, Jisai Chen, Yongzhong Wang, Haitao Xu

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Abstract

The production of sulfur by catalytically reducing SO₂ with CO presents a promising approach for utilizing sulfur oxides found in flue gases. While the novel desulfurization technique exhibits commendable attributes such as heightened efficacy and economical feasibility, its progression is hampered by challenges of catalyst poisoning-induced service life constraints. In this work, the optimization of the Gd@CeO_x catalyst prepared by a hydrothermal process aimed to enhance its resistance to poisoning. The results reveal that the catalyst achieved a conversion of 71.6% and a sulfur yield of 64.6% after a 72 h reaction at 400 °C. This notable performance is ascribed to the hydrothermal synthesis of more porous structures, which improve gas adsorption and activation, as well as increase the presence of alkali on the surface of the Gd@CeO_x catalyst. The reaction mechanism follows both L–H and E–R pathways. This work offers a cost-effective and efficient approach to flue gas desulfurization, with substantial implications for sulfur resource utilization.

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Gd@CeOx催化剂催化还原SO2：稳定性增强和结构调节

用CO催化还原SO2制硫是利用烟道气中硫氧化物的一种很有前途的方法。虽然这种新型脱硫技术具有较高的效率和经济可行性等优点，但其发展受到催化剂中毒引起的使用寿命限制的挑战。本文对水热法制备的Gd@CeOx催化剂进行了优化，以提高其抗中毒性能。结果表明，该催化剂在400℃下反应72 h，转化率为71.6%，硫收率为64.6%。这种显著的性能归因于水热合成了更多的多孔结构，这改善了气体的吸附和活化，同时增加了Gd@CeOx催化剂表面碱的存在。反应机制遵循L-H和E-R两种途径。这项工作为烟气脱硫提供了一种具有成本效益和效率的方法，对硫资源利用具有重大意义。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Environmental Science: Nano CHEMISTRY, MULTIDISCIPLINARY-ENVIRONMENTAL SCIENCES

CiteScore

12.20

自引率

5.50%

发文量

290

审稿时长

2.1 months

期刊介绍： Environmental Science: Nano serves as a comprehensive and high-impact peer-reviewed source of information on the design and demonstration of engineered nanomaterials for environment-based applications. It also covers the interactions between engineered, natural, and incidental nanomaterials with biological and environmental systems. This scope includes, but is not limited to, the following topic areas: Novel nanomaterial-based applications for water, air, soil, food, and energy sustainability Nanomaterial interactions with biological systems and nanotoxicology Environmental fate, reactivity, and transformations of nanoscale materials Nanoscale processes in the environment Sustainable nanotechnology including rational nanomaterial design, life cycle assessment, risk/benefit analysis