Litcius/Paper detail

Thermoelectric properties of two-dimensional magnet CrI <sub>3</sub>

Haohao Sheng, Yijie Zhu, Dongmei Bai, Xiaoshan Wu, Jianli Wang

2020Nanotechnology19 citationsDOI

Abstract

Abstract The thermoelectric, phonon transport, and electronic transport properties of two-dimensional magnet CrI 3 are systematically investigated by combining density functional theory with Boltzmann transport theory. A low lattice thermal conductivity of 1.355 W m −1 K −1 is presented at 300 K due to the low Debye temperature and phonon group velocity. The acoustic modes dominate the lattice thermal conductivity, and the longitudinal acoustic mode has the largest contribution of 42.31% on account of its relatively large phonon group velocity and phonon lifetime. The high band degeneracy and the peaky density of states near the conduction band minimum appear for the CrI 3 monolayer, which is beneficial for forming a significantly increased Seebeck coefficient (1561 μ V K −1 ). Furthermore, the thermoelectric figure of merit is calculated reasonably, and the value is 1.57 for the optimal n-type doping level at 900 K. N-type doping maintains a higher thermoelectric conversion efficiency than p-type doping throughout the temperature range, while the difference gradually increases as the temperature rises. Our investigation may provide some theoretical support for the application of the CrI 3 monolayer in the thermoelectric field.

Topics & Concepts

Condensed matter physicsThermoelectric effectMaterials sciencePhononThermal conductivitySeebeck coefficientDopingThermoelectric materialsDensity functional theoryThermal conductionDensity of statesPhysicsThermodynamicsQuantum mechanicsComposite materialAdvanced Thermoelectric Materials and Devices2D Materials and ApplicationsPerovskite Materials and Applications