Picosecond pulse generation from continuous-wave light in an integrated nonlinear Bragg grating

The generation of optical pulse trains from continuous-wave light has attracted growing attention in recent years because it provides a simple way to obtain high repetition rate ultrashort pulses. While pulse generation has been extensively demonstrated in optical fibers, pulse train generation from weak, continuous wave light in photonic chips has posed significant challenges because of the short interaction length and therefore difficulty in acquiring sufficient new frequency content, and/or absence of the appropriate dispersion environment. In this manuscript, we report the pulse train generation of a low continuous-wave signal to 18 ps, by leveraging cross-phase modulation induced by co-propagating pump pulses with a peak power of 3.7 W in an ultra-silicon-rich nitride grating. The pulse train generation dynamics are documented both experimentally and theoretically to arise from cross-phase modulation-induced generation of new spectral content, and dispersive re-phasing. This is a new approach in which picosecond pulse generation may be achieved from low power, continuous-wave light.

Automated summary

In this manuscript, a new approach for generating picosecond pulse trains from low power, continuous-wave light is introduced. This is achieved by utilizing cross-phase modulation technology in an ultra-silicon-rich nitride grating. The significance of this technique lies in its ability to generate high repetition rate ultrashort pulses from weak continuous-wave light.