Insights of Nanostructured Ferberite as Photocatalyst, Growth Mechanism and Photodegradation Under H₂O₂-Assisted Sunlight.

IF 4.6 2区化学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecules Pub Date : 2025-10-09 DOI:10.3390/molecules30194026

Andarair Gomes Dos Santos, Yassine Elaadssi, Virginie Chevallier, Christine Leroux, Andre Luis Lopes-Moriyama, Madjid Arab

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Abstract

In this study, nanostructured ferberites (FeWO₄) were synthesized via hydrothermal routes in an acidic medium. It was then investigated as an efficient photocatalyst for degrading organic dye molecules, with methylene blue (MB) as a model pollutant. The formation mechanism of ferberite revealed that the physical form of the precursor, FeSO₄·7H₂O, acts as a decisive factor in morphological evolution. Depending on whether it is in a solid or dilute solution form, two distinct nanostructures are produced: nanoplatelets and self-organized microspheres. Both structures are composed of stoichiometric FeWO₄ (Fe: 49%, W: 51%) in a single monoclinic phase (space group P2/c:1) with high purity and crystallinity. The p-type semiconductor behavior was confirmed using Mott-Schottky model and the optical analysis, resulting in small band gap energies (≈1.7 eV) favoring visible absorption light. Photocatalytic tests under simulated solar irradiation revealed rapid and efficient degradation in less than 10 min under near-industrial conditions (pH 5). This was achieved using only a ferberite catalyst and a low concentration of H₂O₂ (4 mM) without additives, dopants, or artificial light sources. Advanced studies based on photocurrent measurements, trapping and stability tests were carried out to identify the main reactive species involved in the photocatalytic process and better understanding of photodegradation mechanisms. These results demonstrate the potential of nanostructured FeWO₄ as a sustainable and effective photocatalyst for water purification applications.

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纳米结构铁素体作为光催化剂、生长机理及其在h2o2辅助下的光降解研究。

在本研究中，采用水热法在酸性介质中合成了纳米结构的FeWO4。然后以亚甲基蓝（MB）为模型污染物，研究了它作为降解有机染料分子的有效光催化剂。铁素体的形成机理表明，前驱体FeSO4·7H2O的物理形态是铁素体形态演化的决定性因素。取决于它是固体形式还是稀溶液形式，会产生两种不同的纳米结构：纳米血小板和自组织微球。这两种结构都是由FeWO4 （Fe: 49%, W: 51%）组成的单斜相（空间群P2/c:1），具有很高的纯度和结晶度。使用Mott-Schottky模型和光学分析证实了p型半导体行为，导致小带隙能量（≈1.7 eV）有利于可见光吸收。在模拟太阳照射下的光催化试验显示，在接近工业条件（pH 5）下，在不到10分钟的时间内快速有效地降解。这是通过使用亚铁酸盐催化剂和低浓度H2O2 （4mm）实现的，没有添加剂、掺杂剂或人工光源。开展了基于光电流测量、捕获和稳定性测试的高级研究，以确定参与光催化过程的主要反应物质，并更好地了解光降解机制。这些结果证明了纳米结构的FeWO4作为一种可持续和有效的水净化光催化剂的潜力。

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

Molecules 化学-有机化学

CiteScore

7.40

自引率

8.70%

发文量

7524

审稿时长

1.4 months

期刊介绍： Molecules (ISSN 1420-3049, CODEN: MOLEFW) is an open access journal of synthetic organic chemistry and natural product chemistry. All articles are peer-reviewed and published continously upon acceptance. Molecules is published by MDPI, Basel, Switzerland. Our aim is to encourage chemists to publish as much as possible their experimental detail, particularly synthetic procedures and characterization information. There is no restriction on the length of the experimental section. In addition, availability of compound samples is published and considered as important information. Authors are encouraged to register or deposit their chemical samples through the non-profit international organization Molecular Diversity Preservation International (MDPI). Molecules has been launched in 1996 to preserve and exploit molecular diversity of both, chemical information and chemical substances.