Ab initio Study of Nonlinear Optical Susceptibilities in Silicon Nanowires

Abstract

Using Time Independent Density Functional Theory (TIDFT) it is shown that the 2nd order optical susceptibilities of narrow (1nm-2nm) Silicon Nanowires (SiNW) are enhanced due to surface termination. The value of (2) is enhanced up to 200 pm/V which is promising a strong Second Harmonic Generation (SHG) in SiNWs. For [100], [110] and [111] SiNWs, yxx component of (2) tensor is 81, 225 and 81 pm/V, respectively. These are in close agreement with (2) values reported for strained silicon waveguides in experiments. The 3rd order susceptibility, (3), is within the range of (0.1-12)x10-18 m2V2 which is close to the experimental values of bulk silicon (0.1-0.2)x10-18 m2V2 for [110] and [100] SiNWs and it is 100 times better for [111] SiNW. This study suggests possibilities of enhancing SHG in SiNWs through symmetry breaking via strain and surface termination/reconstruction as well as suitability of this DFT-based method in predicting nonlinear optical susceptibilities of nano structures.