What question did this study set out to answer?

The aim is to explore current challenges and innovations in thermoelectric materials for energy applications.

March 15, 2026Open Access

Thermoelectric materials: Current challenges and prospects

Key Points

The aim is to explore current challenges and innovations in thermoelectric materials for energy applications.
Review of recent advancements in thermoelectric materials
Analysis of strategies such as nanostructuring and the usage of non-toxic materials
Discussion on the application of artificial intelligence and machine learning in material optimization
Improved efficiency and sustainability of thermoelectric materials noted
Enhanced waste heat recovery capabilities identified
Potential environmental benefits related to energy transition highlighted

Abstract

Thermoelectric (TE) materials make it possible to convert temperature differences directly into electrical energy, or vice versa, through the Seebeck and Peltier effects. Their applications range from waste heat recovery to cooling and thereby contribute to reducing energy losses and environmental impact, making them attractive for the energy transition. Currently, strategies such as nanostructuring, the employment of new non.toxic and abundant materials, as well as the use of artificial intelligence and machine learning to predict new materials and optimize parameters before synthesis are driving the development of more sustainable and efficient alternatives, consolidating TE materials as a technology with great potential in the energy and industrial fields.

Thermoelectric materials: Current challenges and prospects

Key Points

Abstract

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