Machine Learning-Based Predictions for Half-Heusler Phases

IF 3.1 4区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR

Inorganics Pub Date : 2023-12-22 DOI:10.3390/inorganics12010005

K. Bilińska, Maciej J. Winiarski

引用次数: 0

Abstract

Machine learning models (Support Vector Regression) were applied for predictions of several targets for 18-electron half-Heusler phases: a lattice parameter, a bulk modulus, a band gap, and a lattice thermal conductivity. The training subset, which consisted of 47 stable phases, was studied with the use of Density Functional Theory calculations with two Exchange-Correlation Functionals employed (GGA, MBJGGA). The predictors for machine learning models were defined among the basic properties of the elements. The most optimal combinations of predictors for each target were proposed and discussed. Root Mean Squared Errors obtained for the best combinations of predictors for the particular targets are as follows: 0.1 Å (lattice parameters), 11–12 GPa (bulk modulus), 0.22 eV (band gaps, GGA and MBJGGA), and 9–9.5 W/mK (lattice thermal conductivity). The final results of the predictions for a large set of 74 semiconducting half-Heusler compounds were disclosed and compared to the available literature and experimental data. The findings presented in this work encourage further studies with the use of combined machine learning and ab initio calculations.

查看原文本刊更多论文

基于机器学习的半休斯勒相位预测

应用机器学习模型（支持向量回归）预测了 18 电子半休斯勒相的几个目标：晶格参数、体模量、带隙和晶格热导率。训练子集由 47 个稳定相组成，使用密度泛函理论计算进行研究，并采用了两种交换相关函数（GGA、MBJGGA）。机器学习模型的预测因子是根据元素的基本特性确定的。针对每个目标提出并讨论了预测因子的最佳组合。针对特定目标的预测因子最佳组合的均方根误差如下：0.1 Å（晶格参数）、11-12 GPa（体积模量）、0.22 eV（带隙，GGA 和 MBJGGA）和 9-9.5 W/mK（晶格热导率）。对一大批 74 种半导体半休斯勒化合物的最终预测结果进行了披露，并与现有文献和实验数据进行了比较。这项工作中的发现鼓励了使用机器学习和 ab initio 计算相结合的方法开展进一步研究。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Inorganics Chemistry-Inorganic Chemistry

CiteScore

2.80

自引率

10.30%

发文量

193

审稿时长

6 weeks

期刊介绍： Inorganics is an open access journal that covers all aspects of inorganic chemistry research. Topics include but are not limited to: synthesis and characterization of inorganic compounds, complexes and materials structure and bonding in inorganic molecular and solid state compounds spectroscopic, magnetic, physical and chemical properties of inorganic compounds chemical reactivity, physical properties and applications of inorganic compounds and materials mechanisms of inorganic reactions organometallic compounds inorganic cluster chemistry heterogenous and homogeneous catalytic reactions promoted by inorganic compounds thermodynamics and kinetics of significant new and known inorganic compounds supramolecular systems and coordination polymers bio-inorganic chemistry and applications of inorganic compounds in biological systems and medicine environmental and sustainable energy applications of inorganic compounds and materials MD