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新型ACeWO双钙钛矿(A = Ba,Ca)在环境条件内外的合成尝试与结构研究

Synthesis Attempt and Structural Studies of Novel ACeWO Double Perovskites (A = Ba, Ca) in and outside of Ambient Conditions.

作者信息

Wlodarczyk Damian, Amilusik Mikolaj, Kosyl Katarzyna M, Chrunik Maciej, Lawniczak-Jablonska Krystyna, Strankowski Michal, Zajac Marcin, Tsiumra Volodymyr, Grochot Aneta, Reszka Anna, Suchocki Andrzej, Giela Tomasz, Iwanowski Przemyslaw, Bockowski Michal, Przybylinska Hanka

机构信息

Institute of Physics, Polish Academy of Sciences, Ave. Lotnikow 32/46, PL-02668 Warsaw, Poland.

Institute of High Pressure, Polish Academy of Sciences, Sokolowska 29/37, PL-01142 Warsaw, Poland.

出版信息

ACS Omega. 2022 May 23;7(22):18382-18408. doi: 10.1021/acsomega.2c00669. eCollection 2022 Jun 7.

DOI:10.1021/acsomega.2c00669
PMID:35694470
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9178617/
Abstract

This comprehensive work showcases two novel, rock-salt-type minerals in the form of amphoteric cerium-tungstate double perovskite and ilmenite powders created via a high-temperature solid-state reaction in inert gases. The presented studies have fundamental meaning and will mainly focus on a detailed synthesis description of undoped structures, researching their possible polymorphism in various conditions and hinting at some nontrivial physicochemical properties like charge transfer for upcoming optical studies after eventual doping with selectively chosen rare-earth ions. The formerly mentioned, targeted ABB'X group of compounds contains mainly divalent alkali cations in the form of A = Ba, Ca sharing, here, oxygen-arranged clusters (X = O) with purposely selected central ions from f-block B = Ce and d-block B' = W since together they often possess some exotic properties that could be tuned and implemented into futuristic equipment like sensors or energy converters. Techniques like powder XRD, XPS, XAS, EPR, Raman, and FTIR spectroscopies alongside DSC and TG were involved with an intent to thoroughly describe any possible changes within these materials. Mainly, to have a full prospect of any desirable or undesirable phenomena before diving into more complicated subjects like: energy or charge transfer in low temperatures; to reveal whether or not the huge angular tilting generates large enough dislocations within the material's unit cell to change its initial properties; or if temperature and pressure stimuli are responsible for any phase transitions and eventual, irreversible decomposition.

摘要

这部综合性著作展示了两种新型的岩盐型矿物,它们分别以两性铈钨酸双钙钛矿和钛铁矿粉末的形式存在,是通过在惰性气体中进行高温固态反应制备而成的。所呈现的研究具有基础性意义,主要将聚焦于对未掺杂结构的详细合成描述,研究它们在各种条件下可能的多晶型现象,并暗示一些重要的物理化学性质,如在最终用选择性选择的稀土离子掺杂后用于即将开展的光学研究中的电荷转移。前面提到的目标 ABB'X 族化合物主要包含二价碱金属阳离子,形式为 A = Ba、Ca,在这里,与来自 f 区的故意选择的中心离子 B = Ce 和 d 区的 B' = W 共享氧排列的簇(X = O),因为它们通常一起具有一些可以调整并应用于未来设备(如传感器或能量转换器)的奇异特性。粉末 XRD、XPS、XAS、EPR、拉曼光谱和 FTIR 光谱以及 DSC 和 TG 等技术被用于全面描述这些材料内的任何可能变化。主要目的是在深入研究更复杂的主题(如低温下的能量或电荷转移)之前,全面了解任何期望或不期望的现象;揭示巨大的角倾斜是否会在材料的晶胞内产生足够大的位错以改变其初始性质;或者温度和压力刺激是否会导致任何相变以及最终的不可逆分解。

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