Photocatalytic Papers Comprising Au@SnO₂ Nanocrystals Immobilized on Cellulose Nanofibers for Sustainable Dye Degradation.

IF 5.7 Q2 CHEMISTRY, PHYSICAL

ACS Materials Au Pub Date : 2024-12-13 eCollection Date: 2025-03-12 DOI:10.1021/acsmaterialsau.4c00130

Yu-Chen Wei, Huai-En Chang, Pulikkutty Subramaniyan, Shan-Chu Yu, Yung-Jung Hsu, Tzu-En Lin

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Abstract

This work presents the synthesis, characterization, and photocatalytic performance of a sophisticated photocatalytic paper comprising Au@SnO₂ core@shell nanocrystals immobilized on cellulose nanofibers (CNF). The Au@SnO₂/CNF nanocrystal immobilized paper (NIP) is employed as photocatalysts for degradation of rhodamine B (RhB) under simulated sunlight irradiation. Results reveal that the Au@SnO₂/CNF NIP exhibits a notable photocatalytic activity driven by efficient charge separation at the interface of Au and SnO₂. Mechanistic insights into the degradation process indicate that photoexcited electrons in the Au core reduce dissolved oxygen to form superoxide radicals, while photogenerated holes in the SnO₂ valence band oxidize water to generate hydroxyl radicals. These reactive oxygen species, along with the separated holes themselves, contribute to RhB degradation. Importantly, the Au@SnO₂/CNF NIP demonstrates remarkable recyclability toward RhB degradation, retaining 88% of its initial activity after 18 degradation cycles, highlighting its potential for sustainable environmental remediation applications.

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含有Au@SnO2纳米晶体的纤维素纳米纤维固定化光催化纸可持续降解染料。

本文介绍了一种复杂的光催化纸的合成、表征和光催化性能，该纸由固定在纤维素纳米纤维（CNF）上的Au@SnO2 core@shell纳米晶体组成。采用Au@SnO2/CNF纳米晶固定化纸（NIP）作为光催化剂，在模拟日光照射下降解罗丹明B （RhB）。结果表明，Au@SnO2/CNF NIP在Au和SnO2界面的有效电荷分离驱动下表现出显著的光催化活性。对降解过程的机理分析表明，Au核中的光激发电子使溶解氧还原形成超氧自由基，而SnO2价带中的光生空穴则使水氧化生成羟基自由基。这些活性氧，连同分离的空穴本身，有助于RhB的降解。重要的是，Au@SnO2/CNF NIP对RhB降解表现出显著的可回收性，在18个降解循环后仍保持88%的初始活性，突出了其可持续环境修复应用的潜力。

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

ACS Materials Au 材料科学-

CiteScore

5.00

自引率

0.00%

发文量

期刊介绍： ACS Materials Au is an open access journal publishing letters articles reviews and perspectives describing high-quality research at the forefront of fundamental and applied research and at the interface between materials and other disciplines such as chemistry engineering and biology. Papers that showcase multidisciplinary and innovative materials research addressing global challenges are especially welcome. Areas of interest include but are not limited to:Design synthesis characterization and evaluation of forefront and emerging materialsUnderstanding structure property performance relationships and their underlying mechanismsDevelopment of materials for energy environmental biomedical electronic and catalytic applications