Band gap and band alignment prediction of nitride based semiconductors using machine learning

TL;DR

This study combines first-principles calculations and machine learning to accurately predict the band gap and band alignment of nitrides, aiding materials design for optoelectronic applications.

Contribution

It introduces a machine learning approach using elemental features and feature engineering to predict nitride properties with high accuracy, improving upon traditional computational methods.

Findings

Support vector regression with radial kernel performs best among tested models.

Adding DFT-PBE band gap as a feature reduces prediction RMSE to 0.099 eV.

Band gap narrows and band offset increases with more cation types.

Abstract

Nitride has been drawing much attention due to its wide range of applications in optoelectronics and remains plenty of room for materials design and discovery. Here, a large set of nitrides have been designed, with their band gap and alignment being studied by first-principles calculations combined with machine learning. Band gap and band offset against wurtzite GaN accurately calculated by the combination of screened hybrid functional of HSE and DFT-PBE were used to train and test machine learning models. After comparison among different techniques of machine learning, when elemental properties are taken as features, support vector regression (SVR) with radial kernel performs best for predicting both band gap and band offset with prediction root mean square error (RMSE) of 0.298 eV and 0.183 eV, respectively. The former is within HSE calculation uncertainty and the latter is small enough to provide reliable predictions. Additionally, when band gap calculated by DFT-PBE was added into the feature space, band gap prediction RMSE decreases to 0.099 eV. Through a feature engineering algorithm, elemental feature space based band gap prediction RMSE further drops by around 0.005 eV and the relative importance of elemental properties for band gap prediction was revealed. Finally, band gap and band offset of all designed nitrides were predicted and two trends were noticed that as the number of cation types increases, band gap tends to narrow down while band offset tends to go up. The predicted results will be a useful guidance for precise investigation on nitride engineering.