Enhanced Dispersive Waves Generation via Sinusoidally Spectral Phase‐Modulated Pulses

The dispersive waves (DWs) emitted from a Gaussian pulse with an initial sinusoidally spectral phase (SSP) modulation are investigated. By tailoring the modulation depth and frequency, the SSP results in complex pulses shape with a multipulses structure ranging from Airy‐like to pulse sequences having controllable delay and phase. These salient features are able to control and enhance the radiation frequency and energy conversion efficiency of the DWs. The resonant frequencies based on a modified phase‐matching condition are given, which agree with the numerical results obtained by solving the nonlinear Schrödinger equation directly. The results not only further extend the application of the pulse shaping technology in fiber optics, but also provide an alternative approach to manipulate the process of DWs emission which is relevant to the generation broadband supercontinuum as well as frequency comb. The authors report the controllable dispersive wave (DW) emission from a Gaussian pulse modulated by the sinusoidally spectral phase. The multipulse profile and phase can be controlled by tailoring the modulation parameters. The resonant frequency and conversion efficiency of DWs are manipulated. And a modified phase matching condition is given to reveal the resonant frequency of DWs.