Nonlinear electromagnetic response of few-layer graphene: A nonperturbative description

Nonperturbative approach based on exact solution of Boltzmann kinetic equation in the relaxation time approximation isdeveloped for the study of nonlinear response of electron-doped few-layer graphene to a high-frequency electromagnetic field. It isshown that nonperturbative approach can be applied to a two-dimensional conductor with an arbitrary isotropic spectrum of carries.The cases of ABC stacked three-layer and ABC staked four-layer graphene are considered. The low-energy electron spectrum ofsuch graphenes is characterized by the third and the fourth power in the momentum dependence, correspondingly. The transmission,reflection and absorption coefficients are calculated. It is shown that the transmission coefficient T of three- and four-layer graphenedecreases under increase in the intensity of the incident wave I by the asymptotic law 1/2 T I and 2/3 T I , respectively. It isfound that three-layer and four-layer graphenes demonstrate power-induced reflectance, in contrast to power-induced transparency inmonolayer graphene. It is found that in the four-layer graphene irradiated by a monochromatic wave the induced electrical currentcontains only the first and the third harmonics. The analytical expression for the efficiency of the third-harmonic generation GTGH(the ratio of the intensity of third-harmonic radiation to the intensity of the incident wave) of the four-layer graphene is obtained. It isshown that only at rather small incident wave intensity the efficiency GTGH is proportional to the second power of I and at largeincident wave intensity the efficiency GTGH approaches the constant quantity. Saturation of the efficiency of the third-order harmonicgeneration is caused by the increase of the reflection. In contrast, the efficiency of the third-order harmonic generation of monolayergraphene depends nonmonotonically on the intensity of the incident wave. The maximum is reached at rather small intensity I аndthe efficiency in the maximum is of order of 10-4 that is two orders of magnitude smaller than of four-layer graphene.