<p>Designing high-performance thermoelectric (TE) devices is challenging because it requires not only advanced materials but also optimal configurations, which are critical for maximizing device performance but remain time-consuming and resource-intensive to identify<sup><CitationRef AdditionalCitationIDS="CR2 CR3 CR4" CitationID="CR1">1</CitationRef>–<CitationRef CitationID="CR5">5</CitationRef></sup>. Here we develop TEGNet, a neural network emulator that predicts TE generator performance with greater than 99% accuracy while using only 0.01% of the computational time required by commercial finite-element solvers. TEGNet exhibits strong architectural generality across various material systems and allows flexible combinations of material-specific emulators, unlocking rapid and accurate exploration of diverse device architectures. Using TEGNet, we experimentally optimize MgAgSb/Bi<sub>0.4</sub>Sb<sub>1.6</sub>Te<sub>3</sub> segmented and Mg<sub>3</sub>Bi<sub>1.4</sub>Sb<sub>0.6</sub>–MgAgSb n–p paired TE generators, achieving conversion efficiencies of 9.3% and 8.7%, respectively, ranking competitively high among those previously reported<sup><CitationRef AdditionalCitationIDS="CR7 CR8 CR9" CitationID="CR6">6</CitationRef>–<CitationRef CitationID="CR10">10</CitationRef></sup>. This work demonstrates the power of artificial intelligence (AI) in TE generator design, inspiring further research on AI for thermoelectrics.</p>

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Composable neural emulators accelerate thermoelectric generator design

  • Airan Li,
  • Xinzhi Wu,
  • Longquan Wang,
  • Gang Wu,
  • Jiankang Li,
  • Zhao Hu,
  • Xinyuan Wang,
  • Takao Mori

摘要

Designing high-performance thermoelectric (TE) devices is challenging because it requires not only advanced materials but also optimal configurations, which are critical for maximizing device performance but remain time-consuming and resource-intensive to identify15. Here we develop TEGNet, a neural network emulator that predicts TE generator performance with greater than 99% accuracy while using only 0.01% of the computational time required by commercial finite-element solvers. TEGNet exhibits strong architectural generality across various material systems and allows flexible combinations of material-specific emulators, unlocking rapid and accurate exploration of diverse device architectures. Using TEGNet, we experimentally optimize MgAgSb/Bi0.4Sb1.6Te3 segmented and Mg3Bi1.4Sb0.6–MgAgSb n–p paired TE generators, achieving conversion efficiencies of 9.3% and 8.7%, respectively, ranking competitively high among those previously reported610. This work demonstrates the power of artificial intelligence (AI) in TE generator design, inspiring further research on AI for thermoelectrics.