(Nd0.2Li0.2Ba0.2Sr0.2Ca0.2)TiO3高熵包晶的合成与高压特性

IF 3.7 3区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Today Communications Pub Date : 2024-09-07 DOI:10.1016/j.mtcomm.2024.110346

Zhi Zheng, Junwei Li, Xinglong Deng, Mengjun Xiong, Weizhao Cai, Bingliang Liang, Kaihuai Yang, Shenghua Mei

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引用次数: 0

摘要

高熵过氧化物的最新发展表明，它们在各种应用中大有可为。然而，为了满足极端环境应用不断扩大的需求，高熵包晶在高压下的关键特性仍有待揭示。本研究合成了一种 A 位高熵包晶 (NdLiBaSrCa)TiO 。利用金刚石砧室结合全面的原位测量，对其相稳定性、介电性能和带隙进行了高压投资。结果表明，(NdLiBaSrCa)TiO 在高达 15 GPa 的压力下仍保持包晶结构。晶粒电阻随着压力的增加呈指数下降，而在 7 GPa 以下时，晶界电阻发生了异常变化。此外，(NdLiBaSrCa)TiO 在压缩后显示出轻微的带隙增加。我们的多层面方法提供了对高熵包晶石高压行为的全面理解，为设计和优化高压环境下的先进功能材料提供了宝贵的见解。

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Synthesis and high-pressure properties of (Nd0.2Li0.2Ba0.2Sr0.2Ca0.2)TiO3 high-entropy perovskite

The recent development of high-entropy perovskites has demonstrated their tremendous promise for various applications. To meet the expanding needs for extreme environment applications, however, the critical properties of high-entropy perovskite at high pressure remain to be disclosed. In the present work, an A-site high-entropy perovskite (NdLiBaSrCa)TiO was synthesized. High-pressure investment on the phase stability, dielectric properties, and bandgap was conducted using diamond anvil cell combined with comprehensive in-situ measurements. The results reveal that (NdLiBaSrCa)TiO remains the perovskite structure at the pressure up to ∼15 GPa. The grain resistance exhibits an exponential decrease with the increasing pressure, whilst an unusual change of the grain boundary resistance was observed at ∼7 GPa. Furthermore, (NdLiBaSrCa)TiO shows a slight increase of the bandgap upon compression. Our multifaceted approach provides a comprehensive understanding of the high-pressure behavior of high-entropy perovskite, offering valuable insights for the design and optimization of advanced functional materials for high-pressure environments.

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来源期刊

Materials Today Communications Materials Science-General Materials Science

CiteScore

5.20

自引率

5.30%

发文量

1783

审稿时长

51 days

期刊介绍： Materials Today Communications is a primary research journal covering all areas of materials science. The journal offers the materials community an innovative, efficient and flexible route for the publication of original research which has not found the right home on first submission.