Raman-induced dynamics of ultrafast microresonator solitons
Abstract
Soliton microcombs are evolving towards octave-spanning for f-2f self-referencing and expanding applications in spectroscopy and timekeeping. As spectra broaden and pulses shorten, the Raman-induced soliton self-frequency shift (SSFS) becomes a principal limitation: it reduces pump-to-comb conversion efficiency, constrains achievable span, and can, in extremes, preclude stationary operation. We develop a complementary theory of SSFS in microresonators that remains valid when the soliton duration τs is shorter than the Raman response timescale. The theory predicts a reduced dependence of the SSFS on τs which also expands the soliton existence range. Such predictions are validated by numerical simulations and by experiments on Si3N4 microresonators. Our results provide practical guidelines for engineering efficient and broadband soliton microcombs.
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