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Multi-color solitons and frequency combs in microresonators

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arxiv 2409.03880 v1 pith:FJHYE3ZU submitted 2024-09-05 physics.optics math-phmath.MP

Multi-color solitons and frequency combs in microresonators

classification physics.optics math-phmath.MP
keywords frequencycombcombsequationssolitonseffectmicroresonatorsmulti-color
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Multi-color solitons that are parametrically created in dual-pumped microresonators generate interleaved frequency combs that can be used to obtain combs at new frequencies and when synchronized can be used for low-noise microwave generation and potentially as an element in a chip-scale clockwork. Here, we first derive three-wave equations that describe multi-color solitons that appear in microresonators with a nearly quartic dispersion profile. These solitons are characterized by a single angular group velocity and multiple angular phase velocities. We then use these equations to explain the interleaved frequency combs that are observed at the output of the microresonator. Finally, we used these equations to describe the experimentally-observed soliton-OPO effect. In this effect, the pump frequency comb interacts nonlinearly with a signal frequency comb to create an idler frequency comb in a new frequency range, analogous to an optical parametric oscillation (OPO) process. We determine the conditions under which we expect this effect to occur. We anticipate that the three-wave equations and their extensions will be of use in designing new frequency comb systems and determining their stability and noise performance.

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