Photo-excited carriers and optical conductance and transmission in graphene in the presence of phonon scattering

Abstract

We present a theoretical study of the optoelectronic properties of monolayer graphene. Including the effect of the electron–photon–phonon scattering, we employ the mass- and energy-balance equations derived from the Boltzmann equation to evaluate self-consistently the carrier densities, optical conductance and transmission coefficient in graphene in the presence of linearly polarized radiation field. We find that the photo-excited carrier density can be increased under infrared radiation and depend strongly on radiation intensity and frequency. For short wavelengths ( λ < 3 μ m ), the universal optical conductance σ 0 = e 2 / 4 ℏ is obtained and the light transmittance is about 0.97–0.98. Interestingly, there is an optical absorption window in the range 4 – 100 μ m which is induced by different transition energies required for inter- and intra-band optical absorption. The position and width of this absorption window depend sensitively on temperature and carrier density of the system. These results are relevant for applications of recently developed graphene devices in advanced optoelectronics such as the infrared photodetectors.