Electrical and Thermal Transport Properties of Ge<sub>1–</sub><i><sub>x</sub></i>Pb<i><sub>x</sub></i>Cu<i><sub>y</sub></i>Sb<i><sub>y</sub></i>TeSe<sub>2</sub><i><sub>y</sub></i>
Yang Jin, Dudi Ren, Yuting Qiu, Li‐Dong Zhao
Abstract
Abstract Balancing the contradictory relationship between thermoelectric parameters, such as effective mass and carrier mobility, is a challenge to optimize thermoelectric performance. Herein, the exceptional thermoelectric performance is realized in GeTe through collaboratively optimizing the carrier and phonon transport via stepwise alloying Pb and CuSbSe 2 . The formation energy of Ge vacancy is efficiently bolstered by alloying Pb, which reduces carrier density and carrier scattering to maintain superior carrier mobility in GeTe. Additionally, CuSbSe 2 , acting as an n‐type dopant, further modulates carrier density and validly equilibrates carrier mobility and effective mass. Accordingly, the promising power factor of 45 µW cm −1 K −2 is achieved at 723 K. Meanwhile, point defects are found to significantly suppress phonons transport to descend lattice thermal conductivity by Pb and CuSbSe 2 alloying, which barely impacts the carrier mobility. A combination with superior carrier mobility and lower lattice thermal conductivity, a maximum ZT of 2.2 is attained in Ge 0.925 Pb 0.075 Cu 0.005 Sb 0.005 TeSe 0.01 , which corresponds to a 100% promotion compared with that of intrinsic GeTe. This study provides a new indicator for optimizing carrier and phonon transport properties by balancing interrelated thermoelectric parameters.