Temporal evolution and spectral characteristics of dual field in a double-pumped microcavity

Abstract

To generate dual combs for various precision measurements, the temporal evolution and spectral characteristics of dual fields in a double-pumped microcavity are investigated. Results show that by using dual orthogonally polarized pumps, the dual fields can be controlled by regulating the two detunings. The coexistence of solitons and Turing patterns, which is equivalent to dual-frequency combs with a large repetition frequency difference, can be excited. Two positive detuning parameters are similar, and two soliton pulses with identical free spectral ranges and different intensities are formed. Moreover, two weaker positive detunings are beneficial for the dual Turing patterns. Furthermore, breathers and multiple pulses can be excited under special conditions. The effects of dispersion and pump intensity on the dual fields are also studied. Dual combs exist in an anomalous dispersion regime and the strong negative dispersion only leads to DC fields. For the pump intensity, with the increase of pumping power, one field experiences breathers and variable multi-pulse in sequence while the other field maintains Turing patterns. The results of this study provide a new approach to excite dual-frequency combs by using a single microcavity.