锰酸铋和铁酸铋电特性的合成和表征:掺杂对正离子和阴离子亚晶格的影响:应用材料

IF 4.5 2区 材料科学 Q1 CRYSTALLOGRAPHY
A. Molak , D.K. Mahato , A.Z. Szeremeta
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引用次数: 18

摘要

综述了铋锰酸盐(BM)(如BiMnO3)和铋铁氧体(BF)(如BiFeO3)的电、磁和结构特征。感应多铁性和增强磁电耦合是各种现代器件应用所必需的。BM和BF采用标准的高温烧结和溶胶-凝胶、水热或湿化学方法结合退火等工艺合成。纳米级颗粒的大小和形态是可控的,尽管它们通常是不均匀的。高炉在较宽的温度范围内表现出结构稳定的反铁磁相和铁电相。纳米级BF颗粒在AFM核心周围的厚壳层中产生了铁磁有序,这归因于与表面应变和无序相关的尺寸效应。BM既有结构稳定相,也有结构不稳定相。BiMnO3、Bi12MnO20和BiMn2O5为非铁电结构。在高静水压力下合成了钙钛矿型BiMnO3。在低温下BM中出现FM顺序。Bi(MnFe)O3固溶体样品表现出AFM和FM排序的竞争。掺杂可以降低不可避免的二次相的含量。在铋离子亚晶格中掺杂铋离子与掺杂物之间离子半径的差异会引起局部应变,从而使晶格稳定。Fe和Mn亚晶格的掺杂会影响其电学特性。四价和五价离子取代的主要成果是补偿氧空位。反过来,泄漏电流抑制使样品的FE域和极化开关成为可能。由BF和其他FE材料组成的复合材料的磁电耦合显著增强。当绝缘体聚合物基体阻止渗透时,泄漏电流可以减少。潜在的适用性与增强的磁电耦合有关。所构建的器件满足有限元和调频排序的尺寸效应限制。电阻开关可能用于非易失性存储器和气体传感器。该传感器可用于水听器、光伏和光致发光应用,并且可以由多相材料构建。块状多铁固溶体、复合材料和纳米异质结构已经在传感器、传感器和读写设备中进行了技术测试。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Synthesis and characterization of electrical features of bismuth manganite and bismuth ferrite: effects of doping in cationic and anionic sublattice: Materials for applications

Synthesis and characterization of electrical features of bismuth manganite and bismuth ferrite: effects of doping in cationic and anionic sublattice: Materials for applications

The electrical, magnetic, and structural features of bismuth manganite (BM), e.g., BiMnO3, and bismuth ferrite (BF), e.g., BiFeO3, are reviewed. Induced multiferroicity and enhanced magnetoelectric coupling are required for various modern device applications. BM and BF were synthesized using standard high-temperature sintering and processes such as sol–gel, hydrothermal, or wet chemical methods combined with annealing. The size and morphology of the nanoscale particles were controlled, although they were usually inhomogeneous. BF exhibits structurally stable antiferromagnetic (AFM) and ferroelectric (FE) phases in wide temperature ranges. Ferromagnetic (FM) order was induced in a thick shell around the AFM core of the nanoscale BF particles, which was attributed to a size effect related to surface strains and disorder. BM exhibited both structurally stable and unstable phases. The BiMnO3, Bi12MnO20, and BiMn2O5 structures are nonferroelectric. The perovskite BiMnO3 form was synthesized under high hydrostatic pressure. FM order occurs in BM at low temperatures. Bi(MnFe)O3 solid solution samples exhibited competition between AFM and FM ordering. Doping can decrease the content of unavoidable secondary phases. Doping in the Bi ion sublattice can stabilize the crystal lattice owing to local strains caused by the difference in ionic radius between Bi and the dopant. Doping in the Fe and Mn sublattices affects the electrical features. The main achievement of substitution with tetra- and pentavalent ions is compensation of the oxygen vacancies. In turn, leakage current suppression enables switching of FE domains and polarization of the samples. A significant enhancement of magnetoelectric coupling was observed in composites formed from BF and other FE materials. The leakage currents can be diminished when an insulator polymer matrix blocks percolation. The potential applicability is related to enhanced magnetoelectric coupling. The constructed devices meet the size effect limitations for FE and FM ordering. Resistive switching suggests possible use in nonvolatile memories and gaseous sensors. The sensors can be used for hydrophones and for photovoltaic and photoluminescence applications, and they can be constructed from multiphase materials. Bulk multiferroic solid solutions, composites, and nanoheterostructures have already been tested for use in sensors, transducers, and read/write devices for technical purposes.

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来源期刊
Progress in Crystal Growth and Characterization of Materials
Progress in Crystal Growth and Characterization of Materials 工程技术-材料科学:表征与测试
CiteScore
8.80
自引率
2.00%
发文量
10
审稿时长
1 day
期刊介绍: Materials especially crystalline materials provide the foundation of our modern technologically driven world. The domination of materials is achieved through detailed scientific research. Advances in the techniques of growing and assessing ever more perfect crystals of a wide range of materials lie at the roots of much of today''s advanced technology. The evolution and development of crystalline materials involves research by dedicated scientists in academia as well as industry involving a broad field of disciplines including biology, chemistry, physics, material sciences and engineering. Crucially important applications in information technology, photonics, energy storage and harvesting, environmental protection, medicine and food production require a deep understanding of and control of crystal growth. This can involve suitable growth methods and material characterization from the bulk down to the nano-scale.
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