Abstract
The Materials Genome Initiative requires the crossing of material calculations, machine learning, and experiments to accelerate the material development process. In recent years, data-based methods have been applied to the thermoelectric field, mostly on the transport properties. In this work, we combined data-driven machine learning and first-principles automated calculations into an active learning loop, in order to predict the p-type power factors (PFs) of diamond-like pnictides and chalcogenides. Our active learning loop contains two procedures (1) based on a high-throughput theoretical database, machine learning methods are employed to select potential candidates and (2) computational verification is applied to these candidates about their transport properties. The verification data will be added into the database to improve the extrapolation abilities of the machine learning models. Different strategies of selecting candidates have been tested, finally the Gradient Boosting Regression model of Query by Committee strategy has the highest extrapolation accuracy (the Pearson R = 0.95 on untrained systems). Based on the prediction from the machine learning models, binary pnictides, vacancy, and small atom-containing chalcogenides are predicted to have large PFs. The bonding analysis reveals that the alterations of anionic bonding networks due to small atoms are beneficial to the PFs in these compounds.
Highlights
Thermoelectric (TE) materials have aroused widespread interest owing to their potential applications in waste heat harvesting and refrigeration[1,2,3]
We introduce the energy integral of the negative density of energy (-DOE) at the valence band maximum (VBM) to quantify the degree of the destabilizing contribution, which is written as Eband 1⁄4 REf ÀDOEðEÞdE29
The reason for the inaccurate extrapolation results from machine learning (ML) models lies in the lack of samples
Summary
Thermoelectric (TE) materials have aroused widespread interest owing to their potential applications in waste heat harvesting and refrigeration[1,2,3]. The conversion efficiency of TE materials is evaluated by the dimensionless TE figure-of-merit ZT, defined as. SZeTe1⁄4beκcSL2kþσκTec,owefhfiecrieenSt,, σ, κL, κe, electrical and T, respectively, conductivity, lattice stand for the thermal conductivity, electronic thermal conductivity, and the absolute temperature. Because of the intercorrelation between the transport parameters, the improvement of ZT values is challenging[4,5,6]. As computational materials science is emerging, the highthroughput (HTP) calculation methods have been introduced to the TE material field. In 2014, Carrete et al scanned ~79,000 half-. Heusler structures and recommended 3 semiconductors with low lattice thermal conductivities[7].
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