Synergically enhanced piezocatalysis performance of eco-friendly (K0.52Na0.48)NbO3 through ferroelectric polarization and defects

IF 5.6 2区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Min Zhou, Laijun Liang, Dingze Lu, Xiaomei Lu, Zheng Wang, Fengzhen Huang, Pengfei Cheng, Dongdong Liu, Mengqi Tian, Qiuping Wang, Yunjie Zhang
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引用次数: 1

Abstract

Piezocatalysis has attracted unprecedented research interest as a newly emerging catalysis technology. However, the inherent insulating property of ferroelectric materials ultimately leads to the poor vibration–electricity conversion ability. Herein, this work reports the (K0.52Na0.48)NbO3 ferroelectric ceramics (KNNFCx), for which the FeCo modification strategy is proposed. The substitution of the moderate amount of FeCo (x = 0.015) at Nb site not only optimizes ferroelectricity but also produces beneficial defects, notably increasing Rhodamine B water purification efficiency to 95%. The pinning effect of monovalent oxygen vacancies on ferroelectric domains is responsible for the excellent ferroelectric polarization of KNNFC0.015 through the generation of an internal field to promote charge carriers separation and reduce non-radiative recombination. Importantly, the accompanying electron carriers can easily move to the material surface and participate in redox reactions because they have low activation energy. Therefore, ferroelectric polarization and defects play synergetic roles in enhancing piezocatalytic performance.

通过铁电极化和缺陷协同增强环保型(K0.52Na0.48)NbO3的压电催化性能
压电催化作为一种新兴的催化技术,引起了人们前所未有的研究兴趣。然而,铁电材料固有的绝缘性能最终导致了较差的振动-电转换能力。本文报道了(K0.52Na0.48)NbO3铁电陶瓷(KNNFCx),并提出了FeCo改性策略。在Nb位置取代适量的FeCo(x=0.015)不仅优化了铁电性,而且产生了有益的缺陷,显著地将罗丹明B水净化效率提高到95%。铁电畴上单价氧空位的钉扎效应是KNNFC0.015通过产生内部场来促进电荷载流子分离和减少非辐射复合而获得优异铁电极化的原因。重要的是,伴随的电子载流子可以很容易地移动到材料表面并参与氧化还原反应,因为它们具有低活化能。因此,铁电极化和缺陷在提高压电催化性能方面起着协同作用。
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
CiteScore
9.30
自引率
16.70%
发文量
205
审稿时长
2 months
期刊介绍: International Journal of Minerals, Metallurgy and Materials (Formerly known as Journal of University of Science and Technology Beijing, Mineral, Metallurgy, Material) provides an international medium for the publication of theoretical and experimental studies related to the fields of Minerals, Metallurgy and Materials. Papers dealing with minerals processing, mining, mine safety, environmental pollution and protection of mines, process metallurgy, metallurgical physical chemistry, structure and physical properties of materials, corrosion and resistance of materials, are viewed as suitable for publication.
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