Microresonator Isolators and Circulators Based on the Intrinsic Nonreciprocity of the Kerr Effect

2); (2) Heriot-Watt University; 3); (3) Beihang University; Beijing; China); Edinburgh; Jonathan M. Silver (1); Leonardo Del Bino (1; Michael T. M. Woodley (1

arxiv: 1801.09918 · v1 · pith:OCUQA7ROnew · submitted 2018-01-30 · ⚛️ physics.optics · physics.app-ph

Microresonator Isolators and Circulators Based on the Intrinsic Nonreciprocity of the Kerr Effect

Leonardo Del Bino (1 , 2) , Jonathan M. Silver (1) , Michael T. M. Woodley (1 , Sarah L. Stebbings (1) , Xin Xhao (1 , 3) , Pascal Del'Haye (1) ((1) National Physical Laboratory

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Teddington United Kingdom (2) Heriot-Watt University Edinburgh Scotland (3) Beihang University Beijing China)

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classification ⚛️ physics.optics physics.app-ph

keywords lightnonreciprocityopticalcirculatorseffectisolatorskerrmicroresonator

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Nonreciprocal light propagation is important in many applications, ranging from optical telecommunications to integrated photonics. A simple way to achieve optical nonreciprocity is to use the nonlinear interaction between counterpropagating light in a Kerr medium. Within a ring resonator, this leads to spontaneous symmetry breaking, with the result that light of a given frequency can circulate in one direction, but not in both directions simultaneously. In this work, we demonstrate that this effect can be used to realize optical isolators and circulators based on a single ultra- high-Q microresonator. We obtain isolation of more than 24 dB and develop a theoretical model for the power scaling of the attainable nonreciprocity.

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Microresonator Isolators and Circulators Based on the Intrinsic Nonreciprocity of the Kerr Effect

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