Details

Autor(en) / Beteiligte

• Liu, Wei‐Di
• Wang, De‐Zhuang
• Liu, Qingfeng
• Zhou, Wei
• Shao, Zongping
• Chen, Zhi‐Gang

Titel

High‐Performance GeTe‐Based Thermoelectrics: from Materials to Devices

Ist Teil von

• Advanced energy materials, 2020-05, Vol.10 (19), p.n/a

Ort / Verlag

Weinheim: Wiley Subscription Services, Inc

Erscheinungsjahr

2020

Quelle

Wiley Online Library

Beschreibungen/Notizen

• High‐performance GeTe‐based thermoelectrics have been recently attracting growing research interest. Here, an overview is presented of the structural and electronic band characteristics of GeTe. Intrinsically, compared to low‐temperature rhombohedral GeTe, the high‐symmetry and high‐temperature cubic GeTe has a low energy offset between L and Σ points of the valence band, the reduced direct bandgap and phonon group velocity, and as a result, high thermoelectric performance. Moreover, their thermoelectric performance can be effectively enhanced through either carrier concentration optimization, band structure engineering (bandgap reduction, band degeneracy, and resonant state engineering), or restrained lattice thermal conductivity (phonon velocity reduction or phonon scattering). Consequently, the dimensionless figure of merit, ZT values, of GeTe‐based thermoelectric materials can be higher than 2. The mechanical and thermal stabilities of GeTe‐based thermoelectrics are highlighted, and it is found that they are suitable for practical thermoelectric applications except for their high cost. Finally, it is recognized that the performance of GeTe‐based materials can be further enhanced through synergistic effects. Additionally, proper material selection and module design can further boost the energy conversion efficiency of GeTe‐based thermoelectrics. High‐performance GeTe thermoelectrics are attracting increasing research interest. Here, fundamental crystal structures (including electronic band structures and phonon dispersions), thermoelectric performance enhancement strategies, mechanical/thermal stabilities, and device design of GeTe‐based thermoelectric materials are systematically summarized. Subsequently, the future development directions of both material and device designs of GeTe‐based thermoelectrics are identified.