Synergistic optimization of thermoelectric properties in Ca(Yb)Mg2Bi2 composited SnTe based alloy

Abstract

SnTe exhibits inferior thermoelectric performance because of the excess Sn vacancies, large energy offset between the two valence bands, and relatively high lattice thermal conductivity. Therefore, it is necessary to adopt a variety of means to optimize its thermoelectric performance synergistically. Here, the microstructure and thermoelectric properties for Sn0·99In0·01Te composited with CaMg2Bi2 and YbMg2Bi2 are reported. Ca (Yb) and Mg doping decreases the energy offset between the two valence bands, leading to an improved Seebeck coefficient. In addition, Bi and Sn phases gradually precipitate with the increase of alloying amount. The large number of phase interfaces and point defects scatter phonons strongly. Meanwhile, Mg volatilization produces lots of pores at grain boundaries, which play an important role in extending the phonon transmission path. These multiple effects lead to an ultralow lattice thermal conductivity. Consequently, peak ZT of 0.94 and 1.14 at 823 K are attained in Sn0·99In0·01Te-(CaMg2Bi2)0.025 and Sn0·99In0·01Te-(YbMg2Bi2)0.03, corresponding to average ZT (300–823 K) of 0.67 and 0.77, respectively. This work provides an ingenious way to realize extraordinary thermoelectric performance in SnTe.