posted on 2025-01-11, 04:03authored byJingjing Cui, Weibin Xu, Lin Liao, Jingsai Cheng, Songlin Li, Qicai Mei, Chenghao Xie, Chengyun Liao, Jinsong Wu, Qingjie Zhang, Xinfeng Tang, Gangjian Tan
Materials
with high crystallographic symmetry are supposed to be
good thermoelectrics because they have high valley degeneracy (NV) and superb carrier mobility (μ). Binary
GeSe crystallizes in a low-symmetry orthorhombic structure accompanying
the stereoactive 4s lone pairs of Ge. Herein, we rationally modify
GeSe into a high-symmetry rhombohedral structure by alloying with
GeTe based on the valence-shell electron-pair repulsion theory. We
demonstrate that the substitution of Se by Te weakens the stereoactivity
of the Ge lone-pair electrons, resulting in robust rhombohedral structures
of GeSe1–xTex for x ≥ 0.3 at room temperature. The
increase of crystal symmetry not only boosts NV from 2 for orthorhombic GeSe to 9 for rhombohedral GeSe1–xTex but
greatly enhances μ from <5 to >10 cm2 V–1 s–1 (room-temperature values),
thereby remarkably
elevating the power factors by 2 orders of magnitude (26.9 μW
cm–1 K–2 at 638 K for x = 0.5). Surprisingly, despite their higher crystallographic
symmetry, rhombohedral GeSe1–xTex compounds display even lower lattice thermal
conductivities (∼1.0 W m–1 K–1 at 300 K for x = 0.5) than binary GeSe (∼2.5
W m–1 K–1 at 300 K) due to abundant
alloying defects in the Se–Te sublattice and ferroelectric
instability. Altogether, a maximum ZT value of ∼1.1
at 638 K is achieved in rhombohedral GeSe0.5Te0.5, which already outperforms GeTe. This work provides an avenue for
engineering the thermoelectric properties of low-symmetry compounds
containing lone-pair electrons.