Exploring Multicomponent Phase Space to Discover New Materials

IF 1.5 4区 材料科学 Q4 CHEMISTRY, PHYSICAL Journal of Phase Equilibria and Diffusion Pub Date : 2024-07-12 DOI:10.1007/s11669-024-01131-w
Brian Cantor
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Abstract

Multicomponent phase space has been shown to consist of an enormous number of materials with different compositions, the vast majority of which have never been made or investigated, with great potential, therefore, for the discovery of exciting new materials with valuable properties. At the same time, however, the enormous size of multicomponent phase space makes it far from straightforward to identify suitable strategies for exploring the plethora of potential material compositions and difficult, therefore, to be successful in discovering desirable new materials. Unfortunately, all our knowhow and understanding has been developed for materials with relatively few components in relatively limited proportions, with most of our scientific theories relying essentially on linear assumptions of component dilution and independence that no longer apply in concentrated multicomponent materials. Trial and error, controlled substitution, parameterisation, thermodynamic modelling, atomistic modelling and machine learning techniques have all been employed as methods of exploring multicomponent phase space, with varying levels of success, but ultimately none of these techniques has proved capable of delivering consistent or guaranteed results. This paper provides an overview of the different techniques that have been used to explore multicomponent phase space, indicates their main advantages and disadvantages, and describes some of their successes and failures.

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探索多组分相空间,发现新材料
多组分相空间已被证明由大量不同成分的材料组成,其中绝大多数材料从未被制造或研究过,因此具有发现具有宝贵特性的令人兴奋的新材料的巨大潜力。但与此同时,由于多组分相空间的巨大规模,要找到合适的策略来探索大量潜在的材料成分绝非易事,因此很难成功发现理想的新材料。遗憾的是,我们所有的知识和理解都是针对成分相对较少、比例相对有限的材料而开发的,我们的大多数科学理论基本上都依赖于成分稀释和独立性的线性假设,而这些假设在浓缩多组分材料中已不再适用。试错、受控替代、参数化、热力学建模、原子模型和机器学习技术都被用作探索多组分相空间的方法,并取得了不同程度的成功,但最终这些技术都没有被证明能够提供一致或有保证的结果。本文概述了用于探索多组分相空间的不同技术,指出了它们的主要优缺点,并介绍了其中的一些成功和失败之处。
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来源期刊
Journal of Phase Equilibria and Diffusion
Journal of Phase Equilibria and Diffusion 工程技术-材料科学:综合
CiteScore
2.50
自引率
7.10%
发文量
70
审稿时长
1 months
期刊介绍: The most trusted journal for phase equilibria and thermodynamic research, ASM International''s Journal of Phase Equilibria and Diffusion features critical phase diagram evaluations on scientifically and industrially important alloy systems, authored by international experts. The Journal of Phase Equilibria and Diffusion is critically reviewed and contains basic and applied research results, a survey of current literature and other pertinent articles. The journal covers the significance of diagrams as well as new research techniques, equipment, data evaluation, nomenclature, presentation and other aspects of phase diagram preparation and use. Content includes information on phenomena such as kinetic control of equilibrium, coherency effects, impurity effects, and thermodynamic and crystallographic characteristics. The journal updates systems previously published in the Bulletin of Alloy Phase Diagrams as new data are discovered.
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