Universal Model of Optical-Field Electron Tunneling from Two-Dimensional Materials

Abstract

We develop analytical models of optical-field electron tunneling from the edge and surface of two-dimensional (2D) materials, including the effects of reduced dimensionality, non-parabolic energy dispersion, band anisotropy, quasi-time dependent tunneling and emission dynamics indueced by the laser field. We discover a universal scaling between the tunneling current density J and the laser electric field F: In(J/|F|β)1/|F| with β = 3 / 2 in the edge emission and β = 1 in the vertical surface emission, which both are distinctive from the traditional Fowler-Nordheim (FN) model of β = 2. The current density exhibits an unexpected high-field saturation effect due to the reduced dimensionality of 2D materials, which is completely different from the space-charge saturation commonly observed in traditional bulk materials. Our results reveal the dc bias as an efficient method in modulating the optical-field tunneling sub-optical-cycle emission characteristics. Importantly, our model is in excellent agreement with a recent experiment on graphene. Our findings offer a theoretical foundation for the understanding of optical-field tunneling emission from the 2D material system, which is useful for the development of 2D-material based optoelectronics and vacuum nanoelectronics.