Abstract

We show that the group-velocity-led optical event horizon (OEH) in optical fibers provides a convenient way to actively control the propagation property of higher-order solitons by a comparatively weak dispersive wave (DW) pulse.It has been found numerically that clean soliton breakup, a process by which a second-order soliton completely splits into a pair of constituent solitons with vastly different power proportions after interacting with the weak DW pulse, will occur while external DWs become polychromatic.The temporal separation between both constituent solitons can be controlled by adjusting the power of the external DW.The more energetic main soliton is advanced/trailed in time depending on the selected frequency of input DW pulse.We have developed an analytic formalism describing the external acting-force (AF) perturbation.These results provide a fundamental explanation and physical scaling of optical pulse evolution in optical fibers and can find applications in improved supercontinuum sources.