Mechanochemically synthesized MnO2-gCN nanocomposite for photocatalytic dye and phenol degradation: A combined experiment and DFT study

IF 2.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Rajkumar Mandal , Arka Mandal , Moumita Mukherjee , Nayan Pandit , Biswanath Mukherjee
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Abstract

We present the large-scale synthesis of Manganese dioxide-graphitic carbon nitride (MnO2-gCN) nanocomposite using a mechanochemical process. Hydrothermally synthesized rod-shaped MnO2, combined with pyrolyzed gCN powder in appropriate proportions was mechanically ball-milled to form the MnO2-gCN composite structure. The resulting nanocomposite characterized through X-ray diffraction, Fourier transformed infrared spectroscopy, scanning electron microscopy, UV–Vis spectroscopy, and photoluminesce study revealed the successful anchoring of gCN with MnO2 nanostructure. Subsequently, the photocatalytic activity of MnO2-gCN nanocomposite was assessed by studying the degradation of Rhodamine B, Eosin B, Congo red, Methylene Blue dyes and toxic phenol pollutants under UV light exposure. The MnO2-gCN hybrid catalyst demonstrated impressive degradation efficiency, ca. 90% for Rhodamine B dye and 70% for phenol in 3 h and remarkable stability upto three cyclic runs. The superior performance of the composite, in comparison to its individual counterparts (MnO2 or gCN), can be attributed to the effective separation of photogenerated electron-hole (eh+) pairs and the suppression of charge recombination at the interface. First principle based density functional theory calculations also support the experimental findings and the conclusion of this study.

Abstract Image

光催化降解染料和苯酚的机械化学合成 MnO2-gCN 纳米复合材料:实验和 DFT 综合研究
我们采用机械化学工艺大规模合成了二氧化锰-石墨化氮化碳(MnO2-gCN)纳米复合材料。水热合成的棒状二氧化锰与热解的石墨化碳纳米管粉末按适当比例经机械球磨形成二氧化锰-石墨化碳纳米管复合结构。通过 X 射线衍射、傅立叶变换红外光谱、扫描电子显微镜、紫外可见光谱和光致发光研究对所制备的纳米复合材料进行表征,发现 gCN 与 MnO2 纳米结构成功锚定。随后,通过研究紫外光照射下罗丹明 B、曙红 B、刚果红、亚甲蓝染料和有毒酚类污染物的降解情况,评估了 MnO2-gCN 纳米复合材料的光催化活性。MnO2-gCN 混合催化剂的降解效率令人印象深刻,在 3 小时内对罗丹明 B 染料的降解效率约为 90%,对苯酚的降解效率约为 70%,并且在三次循环运行中表现出显著的稳定性。与单独的同类催化剂(MnO2 或 gCN)相比,该复合催化剂的卓越性能可归因于光生电子-空穴(e--h+)对的有效分离以及界面上电荷重组的抑制。基于第一原理的密度泛函理论计算也支持实验结果和本研究的结论。
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
Micro and Nano Engineering
Micro and Nano Engineering Engineering-Electrical and Electronic Engineering
CiteScore
3.30
自引率
0.00%
发文量
67
审稿时长
80 days
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