质子传导氧化物的新兴计算和机器学习方法:材料发现和基础理解。

IF 7.4 3区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Science and Technology of Advanced Materials Pub Date : 2024-10-29 eCollection Date: 2024-01-01 DOI:10.1080/14686996.2024.2416383
Susumu Fujii, Junji Hyodo, Kazuki Shitara, Akihide Kuwabara, Shusuke Kasamatsu, Yoshihiro Yamazaki
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引用次数: 0

摘要

本综述介绍了在一个为期 5 年的质子传导氧化物研究项目中开发的计算和机器学习方法。该项目的主要目标是开发能够帮助发现材料或为复杂质子传导氧化物提供新见解的方法。通过这些方法,发现了三种新的质子传导氧化物,包括包晶和非包晶。在深入研究方面,发现八面体倾斜/畸变和氧亲和性在决定掺杂锆酸钡的质子扩散性和导电性方面起着关键作用。复制交换蒙特卡罗方法揭示了氧化物中真实的缺陷构型、水合行为及其温度依赖性。我们的 "通过解释发现材料 "方法将从计算和实验中获得的新见解或趋势整合到对材料的连续探索中,还发现了质子电导率超过 0.01 S/cm 且在 300 ∘ C 下具有高化学稳定性的过磷酸盐。
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Emerging computational and machine learning methodologies for proton-conducting oxides: materials discovery and fundamental understanding.

This review presents computational and machine learning methodologies developed during a 5-year research project on proton-conducting oxides. The main goal was to develop methodologies that could assist in materials discovery or provide new insights into complex proton-conducting oxides. Through these methodologies, three new proton-conducting oxides, including both perovskite and non-perovskites, have been discovered. In terms of gaining insights, octahedral tilt/distortions and oxygen affinity are found to play a critical role in determining proton diffusivities and conductivities in doped barium zirconates. Replica exchange Monte Carlo approach has enabled to reveal realistic defect configurations, hydration behavior, and their temperature dependence in oxides. Our approach 'Materials discovery through interpretation', which integrates new insights or tendencies obtained from computations and experiments to sequential explorations of materials, has also identified perovskites that exhibit proton conductivity exceeding 0.01 S/cm and high chemical stability at 300   C.

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来源期刊
Science and Technology of Advanced Materials
Science and Technology of Advanced Materials 工程技术-材料科学:综合
CiteScore
10.60
自引率
3.60%
发文量
52
审稿时长
4.8 months
期刊介绍: Science and Technology of Advanced Materials (STAM) is a leading open access, international journal for outstanding research articles across all aspects of materials science. Our audience is the international community across the disciplines of materials science, physics, chemistry, biology as well as engineering. The journal covers a broad spectrum of topics including functional and structural materials, synthesis and processing, theoretical analyses, characterization and properties of materials. Emphasis is placed on the interdisciplinary nature of materials science and issues at the forefront of the field, such as energy and environmental issues, as well as medical and bioengineering applications. Of particular interest are research papers on the following topics: Materials informatics and materials genomics Materials for 3D printing and additive manufacturing Nanostructured/nanoscale materials and nanodevices Bio-inspired, biomedical, and biological materials; nanomedicine, and novel technologies for clinical and medical applications Materials for energy and environment, next-generation photovoltaics, and green technologies Advanced structural materials, materials for extreme conditions.
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