Electric Field-Induced Second Order Nonlinear Optical Effects in Silicon Waveguides

Abstract

The demand for nonlinear effects within a silicon platform to support photonic circuits requiring phase-only modulation, frequency doubling, and/or difference frequency generation, is becoming increasingly clear. However, the symmetry of the silicon crystal inhibits second order optical nonlinear susceptibility, (2). Here, we show that the crystalline symmetry is broken when a DC field is present, inducing a (2) in a silicon waveguide that is proportional to the large (3) of silicon. First, Mach-Zehnder interferometers using the DC Kerr effect optical phase shifters in silicon ridge waveguides with p-i-n junctions are demonstrated with a VπL of 2.4Vcm in telecom bands (λω=1.58μm) without requiring to dope the silicon core. Second, the pump and second harmonic modes in silicon ridge waveguides are quasi-phase matched when the magnitude, spatial distribution of the DC field and (2) are controlled with p-i-n junctions. Using these waveguides, second harmonic generation at multiple pump wavelengths are observed with a maximum efficiency of P2ω/Pω2=12%/W at λω=2.29μm in a 1mm long waveguide. This corresponds to a field-induced (2)=41pm/V, comparable to non-centrosymmetric media (LiNbO3, GaAs, GaN). The field-induced nonlinear silicon photonics will lead to a new class of CMOS compatible integrated devices spanning from near to mid infrared spectrum.