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Achieving High‐Performance Ge<sub>0.92</sub>Bi<sub>0.08</sub>Te Thermoelectrics via LaB<sub>6</sub>‐Alloying‐Induced Band Engineering and Multi‐Scale Structure Manipulation

Qiang Sun, Xiao‐Lei Shi, Min Hong, Yu Yin, Shengduo Xu, Jie Chen, Lei Yang, Jin Zou, Zhi‐Gang Chen

2021Small11 citationsDOI

Abstract

Abstract In this work, a LaB 6 ‐alloying strategy is reported to effectively boost the figure‐of‐merit (ZT) of Ge 0.92 Bi 0.08 Te‐based alloys up to ≈2.2 at 723 K, attributed to a synergy of La‐dopant induced band structuring and structural manipulation. Density‐function‐theory calculations reveal that La dopant enlarges the bandgap and converges the energy offset between the sub‐valence bands in cubic‐structured GeTe, leading to a significantly increased effective mass, which gives rise to a high Seebeck coefficient of ≈263 µV K −1 and in turn a superior power factor of ≈43 µW cm −1 K −2 at 723 K. Besides, comprehensive electron microscopy characterizations reveal that the multi‐scale phonon scattering centers, including a high density of planar defects, Boron nanoparticles in tandem with enhanced boundaries, dispersive Ge nanoprecipitates in the matrix, and massive point defects, contribute to a low lattice thermal conductivity of ≈0.67 W m −1 K −1 at 723 K. Furthermore, a high microhardness of ≈194 H v is witnessed in the as‐designed Ge 0.92 Bi 0.08 Te(LaB 6 ) 0.04 alloy, derived from the multi‐defect‐induced strengthening. This work provides a strategy for developing high‐performance and mechanical robust middle‐temperature thermoelectric materials for practical thermoelectric applications.

Topics & Concepts

Materials scienceThermoelectric effectDopantThermoelectric materialsCondensed matter physicsBand gapSeebeck coefficientBand offsetOptoelectronicsNanotechnologyThermal conductivityDopingComposite materialThermodynamicsValence bandPhysicsAdvanced Thermoelectric Materials and DevicesThermal properties of materialsThermal Expansion and Ionic Conductivity
Achieving High‐Performance Ge<sub>0.92</sub>Bi<sub>0.08</sub>Te Thermoelectrics via LaB<sub>6</sub>‐Alloying‐Induced Band Engineering and Multi‐Scale Structure Manipulation | Litcius