Photocatalytic Degradation of Malachite Green by NiAl-LDH Intercalated Polyoxometalate Compound

Bulletin of Chemical Reaction Engineering & Catalysis Pub Date : 2022-09-21 DOI:10.9767/bcrec.17.3.15418.627-637

Yuliza Hanifah, R. Mohadi, M. Mardiyanto, A. Lesbani

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引用次数: 4

Abstract

Composites based on layered double hydroxide with polyoxometalate K3[-PW12O40] and K4[-SiW12O40] were synthesized to form NiAl-[SiW12O40] and NiAl-[PW12O40]. The materials were characterized by XRD, FTIR, SEM, and UV-DRS and were then applied as a photocatalyst to degrade MG. The effects of catalyst loading, pH value, and contact times on photodegradation performance were carried out in this study. The results indicated that NiAl-LDH was successfully synthesized by showing the peak diffractions at angles 11.63°, 23.13°, and 35.16°. Both kinds of attained NiAl-[SiW12O40] and NiAl-[PW12O40] had typical structures of LDH that were proved by appearing diffraction at 2θ angles 10.76°, 26.59°, 30.8°, and 63.11° for NiAl-[PW12O40] and at 2θ angles 8.26°, 11.34°, 29°, and 35.1° for NiAl-[SiW12O40]. The materials used for the fifth regeneration were characterized by FTIR, which still presents characteristics of LDH structure. The photocatalyst was applied for the first time to degrade MG. The decrease of band gap on NiAl pristine than LDH composite from 4.76 eV to 3.22 eV for NiAl-[SiW12O40] and 3.78 eV for NiAl-[PW12O40] respectively, was presented by DR-UV analysis. LDH composite shows improved degradation photocatalytic performance in comparison with LDH pristine. It was present by the %degradation MG performances were 68.94% for NiAl LDH, 84.51% for NiAl-[PW12O40]), and 88.91% for NiAl-[SiW12O40]. The degradation percentage indicates that the LDH-polyoxometalate composite has succeeded in increasing the ability of photodegradation catalytic and the regeneration ability of LDH pristine. Copyright © 2022 by Authors, Published by BCREC Group. This is an open access article under the CC BY-SA License (https://creativecommons.org/licenses/by-sa/4.0).

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NiAl-LDH插层多金属酸氧化合物光催化降解孔雀石绿的研究

合成了层状双氢氧化物与多金属氧酸盐K3[PW12O40]和K4[SiW12O40]复合材料，得到NiAl-[SiW12O40]和NiAl-[PW12O40]。采用XRD、FTIR、SEM和UV-DRS对材料进行了表征，并将其作为光催化剂用于MG的降解。研究了催化剂负载、pH值和接触次数对光降解性能的影响。结果表明，NiAl-LDH在11.63°、23.13°和35.16°衍射峰处成功合成。所得到的NiAl-[SiW12O40]和NiAl-[PW12O40]具有典型的LDH结构，NiAl-[PW12O40]的2θ角为10.76°、26.59°、30.8°和63.11°，NiAl-[SiW12O40]的2θ角为8.26°、11.34°、29°和35.1°。用FTIR对第五次再生材料进行了表征，材料仍具有LDH结构的特征。首次将光催化剂应用于MG的降解。DR-UV分析表明，NiAl-[SiW12O40]和NiAl-[PW12O40]的禁带隙分别从4.76 eV和3.78 eV减小到3.22 eV。LDH复合材料与LDH原始材料相比，具有更好的降解光催化性能。对NiAl- LDH、NiAl-[PW12O40]和NiAl-[SiW12O40]的降解率分别为68.94%、84.51%和88.91%。降解率表明LDH-多金属氧酸酯复合材料成功地提高了LDH原始材料的光降解催化能力和再生能力。版权所有©2022作者所有，BCREC集团出版。这是一篇基于CC BY-SA许可(https://creativecommons.org/licenses/by-sa/4.0)的开放获取文章。

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Bulletin of Chemical Reaction Engineering & Catalysis

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