Litcius/Paper detail

Surprisingly good thermoelectric performance of monolayer C <sub>3</sub> N

W Y Jiao, Rui Hu, Shulin Han, Yu-Qing Luo, Hongmei Yuan, M K Li, Huijun Liu

2021Nanotechnology17 citationsDOI

Abstract

Abstract The rapid emergence of graphene has attracted numerous efforts to explore other two-dimensional materials. Here, we combine first-principles calculations and Boltzmann theory to investigate the structural, electronic, and thermoelectric transport properties of monolayer C 3 N, which exhibits a honeycomb structure very similar to graphene. It is found that the system is both dynamically and thermally stable even at high temperature. Unlike graphene, the monolayer has an indirect band gap of 0.38 eV and much lower lattice thermal conductivity. Moreover, the system exhibits obviously larger electrical conductivity and Seebeck coefficients for the hole carriers. Consequently, the ZT value of p -type C 3 N can reach 1.4 at 1200 K when a constant relaxation time is predicted by the simple deformation potential theory. However, such a larger ZT is reduced to 0.6 if we fully consider the electron–phonon coupling. Even so, the thermoelectric performance of monolayer C 3 N is still significantly enhanced compared with that of graphene, and is surprisingly good for low-dimensional thermoelectric materials consisting of very light elements.

Topics & Concepts

Materials scienceThermoelectric effectMonolayerGrapheneCondensed matter physicsElectrical resistivity and conductivityBand gapSeebeck coefficientPhononBoltzmann constantThermoelectric materialsElectronic band structureElectron mobilityThermal conductivityHoneycomb structureNanotechnologyOptoelectronicsThermodynamicsComposite materialPhysicsQuantum mechanicsAdvanced Thermoelectric Materials and Devices2D Materials and ApplicationsGraphene research and applications