Schottky heterojunction-based photocatalysis-in-situ-self-Fenton system: Removal of tetracycline hydrochloride and biotoxicity evaluation of intermediates

Applied Catalysis B: Environment and Energy Pub Date : 2024-08-25 DOI:10.1016/j.apcatb.2024.124533

Qiang Li, Qi Zhou, Hao Deng, Zhiheng Li, Biao Xue, Aoxiang Liu, Bo Shen, Derek Hao, Huayue Zhu, Qi Wang

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Abstract

Efficiently removing tetracycline hydrochloride (TC) while minimizing the formation of toxic intermediates is a significant challenge. A novel photocatalysis-in-situ-self-Fenton catalyst, RF/EA-Fe@TiC, removed 92 % of TC (20 mg L, 100 mL) under visible light irradiation within 80 min. The results of optical thickness and local volumetric rate of photon absorption demonstrated that RF/EA-Fe@TiC had superior light capture ability than that of RF/EA-Fe. TC significantly inhibited wheat seed germination, seedling growth, and chlorophyll and carotenoid generation, whereas its intermediates had a lesser effect. Additionally, TC damaged the photosystem II (PSII) of wheat seedlings, reducing light response ability and energy capture efficiency, while TC intermediates caused damage similar to deionized water. The rapid TC degradation and low-ecotoxic intermediates stem from the synergistic effects between photogenerated holes and hydroxyl radicals. This study advanced the design of photocatalysis-in-situ-self-Fenton systems for antibiotic degradation and detoxification.

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基于肖特基异质结的原位自芬顿光催化系统：盐酸四环素的去除和中间产物的生物毒性评估

高效去除盐酸四环素（TC），同时尽量减少有毒中间产物的形成是一项重大挑战。新型光催化原位自芬顿催化剂 RF/EA-Fe@TiC 在可见光照射下，80 分钟内去除 92% 的 TC（20 mg L，100 mL）。光学厚度和光子吸收局部体积率的结果表明，RF/EA-Fe@TiC 的光捕获能力优于 RF/EA-Fe。三氯乙酸对小麦种子萌发、幼苗生长、叶绿素和类胡萝卜素的生成有明显的抑制作用，而其中间产物的影响较小。此外，TC 还会损害小麦幼苗的光系统 II（PSII），降低光响应能力和能量捕获效率，而 TC 中间体造成的损害与去离子水相似。TC 的快速降解和低生态毒性中间产物源于光生空穴和羟基自由基之间的协同效应。这项研究推动了用于抗生素降解和解毒的光催化原位自芬顿系统的设计。

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Applied Catalysis B: Environment and Energy

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