Full prediction of band potentials in semiconductor materials

IF 10 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Materials Today Physics Pub Date : 2024-08-01 DOI:10.1016/j.mtphys.2024.101519
Yousof Haghshenas , Wei Ping Wong , Vidhyasaharan Sethu , Rose Amal , Priyank Vijaya Kumar , Wey Yang Teoh
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Abstract

A machine learning (ML) framework to predict the physical band potentials for a range of semiconductor materials, from metal sulfide, oxide, and nitride, to oxysulfide and oxynitride, is hereby described. A valence band maximum (VBM) model was established via the transfer learning of a large dataset of 2D materials (1382 samples, but with incorrect VBM potentials) onto a much smaller dataset of physically measured VBM for bulk 3D materials (87 samples) on a crystal graph convolutional neural network. This resulted in predictions with experimental accuracy (RMSE = 0.27 eV), which is a 3-fold improvement compared with ML trained on the physical dataset without transfer learning (RMSE = 0.75 eV). When combined with the bandgap prediction model (RMSE = 0.29 eV), a full prediction of conduction and valence band potentials can be made, which to the best of our knowledge, is the first for any ML framework. The variation of band potentials across low-index surfaces was predicted correctly and verified with reported physical potentials. In fact, the framework is able to capture variation in band potentials associated with minor atomic position alterations. Based on this, a general trend between surface atomic displacement and VBM shift was observed across various semiconductor materials. The model is not yet able to cope with major rearrangement of atomic sequence on surface layers, i.e., surface reconstructions, since it was not trained with such data but can be easily done so with specifically designed dataset. As an example application, the ML framework was used for the screening of potential photocatalytic materials for visible light water splitting. A total of 824 materials was successfully identified, including those experimentally-verified in the literature.

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全面预测半导体材料的带电位
本文介绍了一种机器学习(ML)框架,用于预测从金属硫化物、氧化物和氮化物到氧化硫和氧化氮化物等一系列半导体材料的物理带电位。在晶体图卷积神经网络上,通过将大量二维材料数据集(1382 个样本,但 VBM 电位不正确)转移学习到体积更小的三维材料物理测量 VBM 数据集(87 个样本)上,建立了价带最大值(VBM)模型。这使得预测结果具有实验准确性(RMSE = 0.27 eV),与在没有迁移学习的物理数据集上训练的 ML(RMSE = 0.75 eV)相比提高了 3 倍。当与带隙预测模型(RMSE = 0.29 eV)相结合时,可以对导带和价带电位进行全面预测,据我们所知,这是所有 ML 框架中的第一例。对低指数表面的能带电位变化进行了正确预测,并与报告的物理电位进行了验证。事实上,该框架能够捕捉与原子位置微小变化相关的带电位变化。在此基础上,在各种半导体材料中观察到了表面原子位移和 VBM 移动之间的一般趋势。该模型还无法处理表面层原子序列的重大重新排列,即表面重构,因为它没有经过此类数据的训练,但可以通过专门设计的数据集轻松完成。作为一个应用实例,ML 框架被用于筛选潜在的光催化材料,用于可见光水分离。共成功识别出 824 种材料,其中包括文献中经过实验验证的材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Materials Today Physics
Materials Today Physics Materials Science-General Materials Science
CiteScore
14.00
自引率
7.80%
发文量
284
审稿时长
15 days
期刊介绍: Materials Today Physics is a multi-disciplinary journal focused on the physics of materials, encompassing both the physical properties and materials synthesis. Operating at the interface of physics and materials science, this journal covers one of the largest and most dynamic fields within physical science. The forefront research in materials physics is driving advancements in new materials, uncovering new physics, and fostering novel applications at an unprecedented pace.
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