AI-Driven Defect Engineering for Advanced Thermoelectric Materials

Chu Liang Fu; Mouyang Cheng; Nguyen Tuan Hung; Eunbi Rha; Zhantao Chen; Ryotaro Okabe; Denisse Córdova Carrizales; Manasi Mandal; Yongqiang Cheng; Mingda Li

doi:10.1002/adma.202505642

AI-Driven Defect Engineering for Advanced Thermoelectric Materials

Chu Liang Fu
, Mouyang Cheng
, Nguyen Tuan Hung
, Eunbi Rha
, Zhantao Chen
, Ryotaro Okabe
, Denisse Córdova Carrizales
, Manasi Mandal
, Yongqiang Cheng
, Mingda Li

Chemical Spectroscopy

Research output: Contribution to journal › Review article › peer-review

5 Scopus citations

Abstract

Thermoelectric materials offer a promising pathway to directly convert waste heat to electricity. However, achieving high performance remains challenging due to intrinsic trade-offs between electrical conductivity, the Seebeck coefficient, and thermal conductivity, which are further complicated by the presence of defects. This review explores how artificial intelligence (AI) and machine learning (ML) are transforming thermoelectric materials design. Advanced ML approaches including deep neural networks, graph-based models, and transformer architectures, integrated with high-throughput simulations and growing databases, effectively capture structure-property relationships in a complex multiscale defect space and overcome the “curse of dimensionality”. This review discusses AI-enhanced defect engineering strategies such as composition optimization, entropy and dislocation engineering, and grain boundary design, along with emerging inverse design techniques for generating materials with targeted properties. Finally, it outlines future opportunities in novel physics mechanisms and sustainability, highlighting the critical role of AI in accelerating the discovery of thermoelectric materials.

Original language	English
Article number	2505642
Journal	Advanced Materials
Volume	37
Issue number	35
DOIs	https://doi.org/10.1002/adma.202505642
State	Published - Sep 4 2025

Funding

C.-L.F., M.C. and N.T.H. contributed equally to this work. C.F. and M.C. acknowledged support from the U.S. Department of Energy (DOE), Office of Science (SC), Basic Energy Sciences (BES), Award No. DE-SC0021940. R.O. acknowledged support from the National Science Foundation (NSF) Designing Materials to Revolutionize and Engineer the Future (DMREF) Program with Award No. DMR-2118448. E.R. and D.C.CC acknowledged support from DOE BES Award No. DE-S0020148. M.L. acknowledged the Class of 1947 Career Development Chair and the support from R. Wachnik. Y.C. was supported by the Scientific User Facilities Division, BES, DOE, under Contract No. DE-AC0500OR22725 with UT Battelle, LLC. Open Access funding enabled and organized by MIT Hybrid 2025. C.‐L.F., M.C. and N.T.H. contributed equally to this work. C.F. and M.C. acknowledged support from the U.S. Department of Energy (DOE), Office of Science (SC), Basic Energy Sciences (BES), Award No. DE‐SC0021940. R.O. acknowledged support from the National Science Foundation (NSF) Designing Materials to Revolutionize and Engineer the Future (DMREF) Program with Award No. DMR‐2118448. E.R. and D.C.CC acknowledged support from DOE BES Award No. DE‐S0020148. M.L. acknowledged the Class of 1947 Career Development Chair and the support from R. Wachnik. Y.C. was supported by the Scientific User Facilities Division, BES, DOE, under Contract No. DE‐AC0500OR22725 with UT Battelle, LLC.

Keywords

artificial intelligence
defect engineering
machine learning
thermoelectrics

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10.1002/adma.202505642

Cite this

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title = "AI-Driven Defect Engineering for Advanced Thermoelectric Materials",

abstract = "Thermoelectric materials offer a promising pathway to directly convert waste heat to electricity. However, achieving high performance remains challenging due to intrinsic trade-offs between electrical conductivity, the Seebeck coefficient, and thermal conductivity, which are further complicated by the presence of defects. This review explores how artificial intelligence (AI) and machine learning (ML) are transforming thermoelectric materials design. Advanced ML approaches including deep neural networks, graph-based models, and transformer architectures, integrated with high-throughput simulations and growing databases, effectively capture structure-property relationships in a complex multiscale defect space and overcome the “curse of dimensionality”. This review discusses AI-enhanced defect engineering strategies such as composition optimization, entropy and dislocation engineering, and grain boundary design, along with emerging inverse design techniques for generating materials with targeted properties. Finally, it outlines future opportunities in novel physics mechanisms and sustainability, highlighting the critical role of AI in accelerating the discovery of thermoelectric materials.",

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AU - Cheng, Mouyang

AU - Hung, Nguyen Tuan

AU - Rha, Eunbi

AU - Chen, Zhantao

AU - Okabe, Ryotaro

AU - Carrizales, Denisse Córdova

AU - Mandal, Manasi

AU - Cheng, Yongqiang

AU - Li, Mingda

PY - 2025/9/4

Y1 - 2025/9/4

N2 - Thermoelectric materials offer a promising pathway to directly convert waste heat to electricity. However, achieving high performance remains challenging due to intrinsic trade-offs between electrical conductivity, the Seebeck coefficient, and thermal conductivity, which are further complicated by the presence of defects. This review explores how artificial intelligence (AI) and machine learning (ML) are transforming thermoelectric materials design. Advanced ML approaches including deep neural networks, graph-based models, and transformer architectures, integrated with high-throughput simulations and growing databases, effectively capture structure-property relationships in a complex multiscale defect space and overcome the “curse of dimensionality”. This review discusses AI-enhanced defect engineering strategies such as composition optimization, entropy and dislocation engineering, and grain boundary design, along with emerging inverse design techniques for generating materials with targeted properties. Finally, it outlines future opportunities in novel physics mechanisms and sustainability, highlighting the critical role of AI in accelerating the discovery of thermoelectric materials.

AB - Thermoelectric materials offer a promising pathway to directly convert waste heat to electricity. However, achieving high performance remains challenging due to intrinsic trade-offs between electrical conductivity, the Seebeck coefficient, and thermal conductivity, which are further complicated by the presence of defects. This review explores how artificial intelligence (AI) and machine learning (ML) are transforming thermoelectric materials design. Advanced ML approaches including deep neural networks, graph-based models, and transformer architectures, integrated with high-throughput simulations and growing databases, effectively capture structure-property relationships in a complex multiscale defect space and overcome the “curse of dimensionality”. This review discusses AI-enhanced defect engineering strategies such as composition optimization, entropy and dislocation engineering, and grain boundary design, along with emerging inverse design techniques for generating materials with targeted properties. Finally, it outlines future opportunities in novel physics mechanisms and sustainability, highlighting the critical role of AI in accelerating the discovery of thermoelectric materials.

KW - artificial intelligence

KW - defect engineering

KW - machine learning

KW - thermoelectrics

UR - https://www.scopus.com/pages/publications/105008571268

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M3 - Review article

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VL - 37

JO - Advanced Materials

JF - Advanced Materials

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M1 - 2505642

ER -

AI-Driven Defect Engineering for Advanced Thermoelectric Materials

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