Promising Thermoelectric Performance in Two-Dimensional Semiconducting Boron Monolayer

Yonglan Hu; Ding Li; Rongkun Liu; Shichang Li; Chunbao Feng; Dengfeng Li; Guangqian Ding

doi:10.3389/fchem.2021.739984

Promising Thermoelectric Performance in Two-Dimensional Semiconducting Boron Monolayer

Front Chem. 2021 Sep 22:9:739984. doi: 10.3389/fchem.2021.739984. eCollection 2021.

Authors

Yonglan Hu¹, Ding Li¹, Rongkun Liu¹, Shichang Li¹, Chunbao Feng¹, Dengfeng Li¹, Guangqian Ding¹

Affiliation

¹ School of Science, Chongqing University of Posts and Telecommunications, Chongqing, China.

Abstract

A heavy element is a special character for high thermoelectric performance since it generally guarantees a low lattice thermal conductivity. Here, we unexpectedly found a promising thermoelectric performance in a two-dimensional semiconducting monolayer consisting of a light boron element. Using first-principles combined with the Boltzmann transport theory, we have shown that in contrast to graphene or black phosphorus, the boron monolayer has a low lattice thermal conductivity arising from its complex crystal of hexagonal vacancies. The conduction band with an intrinsic camelback shape leads to the high DOS and a high n-type Seebeck coefficient, while the highly degenerate valence band along with the small hole effective mass contributes to the high p-type power factor. As a result, we obtained the p-type thermoelectric figure of merit up to 0.96 at 300 K, indicating that the boron monolayer is a promising p-type thermoelectric material.

Keywords: Boltzmann; boron monolayer; first-principles; phonon; thermoelectric.