Charge-Selective Photocatalytic Degradation of Organic Dyes Driven by Naturally Occurring Halloysite Nanotubes

Photochem Pub Date : 2024-03-28 DOI:10.3390/photochem4020009
Ashim Pramanik, M. M. Calvino, L. Sciortino, P. Pasbakhsh, G. Cavallaro, G. Lazzara, Fabrizio Messina, A. Sciortino
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Abstract

This study explores the use of Halloysite NanoTubes (HNTs) as photocatalysts capable of decomposing organic dyes under exposure to visible or ultraviolet light. Through a systematic series of photocatalytic experiments, we unveil that the photodegradation of Rhodamine B, used as a model cationic dye, is significantly accelerated in the presence of HNTs. We observe that the extent of RhB photocatalytic degradation in 100 min in the presence of the HNTs is ~four times higher compared to that of bare RhB. Moreover, under optimized conditions, the as-extracted photodegradation rate of RhB (~0.0022 min−1) is comparable to that of the previously reported work on the photodegradation of RhB in the presence of tubular nanostructures. A parallel effect is observed for anionic Coumarin photodegradation, albeit less efficiently. Our analysis attributes this discrepancy to the distinct charge states of the two dyes, influencing their attachment sites on HNTs. Cationic Rhodamine B molecules preferentially attach to the outer surface of HNTs, while anionic Coumarin molecules tend to attach to the inner surface. By leveraging the unique properties of HNTs, a family of naturally occurring nanotube structures, this research offers valuable insights for optimizing photocatalytic systems in the pursuit of effective and eco-friendly solutions for environmental remediation.
天然存在的霍洛石纳米管驱动的电荷选择性有机染料光催化降解
本研究探讨了如何利用霍洛石纳米管(HNT)作为光催化剂,在可见光或紫外线照射下分解有机染料。通过一系列系统的光催化实验,我们发现在 HNTs 的存在下,以罗丹明 B 为模型的阳离子染料的光降解速度明显加快。我们观察到,在 HNT 的存在下,RhB 在 100 分钟内的光催化降解程度是裸 RhB 的四倍。此外,在优化条件下,RhB 的萃取光降解率(~0.0022 min-1)与之前报道的管状纳米结构存在时的 RhB 光降解率相当。阴离子香豆素的光降解也有类似的效果,尽管效率较低。我们的分析将这种差异归因于两种染料不同的电荷状态,影响了它们在 HNT 上的附着点。阳离子罗丹明 B 分子优先附着在 HNT 的外表面,而阴离子香豆素分子则倾向于附着在内表面。通过利用 HNT(一种天然存在的纳米管结构)的独特性质,这项研究为优化光催化系统提供了宝贵的见解,从而为环境修复提供了有效的生态友好型解决方案。
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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CiteScore
3.60
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