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Paper detail

Spontaneous mirror-symmetry breaking in a photonic molecule

Multi-cavity photonic systems, known as photonic molecules (PMs), are ideal multi-well potential building blocks for advanced quantum and nonlinear optics. A key phenomenon arising in double well potentials is the spontaneous breaking of the inversion symmetry, i.e. a transition from a delocalized to two localized states in the wells, which are mirror images of each other. Although few theoretical studies have addressed mirror-symmetry breaking in micro and nanophotonic systems, no experimental evidence has been reported to date. Thanks to the potential barrier engineering implemented here, we demonstrate spontaneous mirror-symmetry breaking through a pitchfork bifurcation in a PM composed of two coupled photonic crystal nanolasers. Coexistence of localized states is shown by switching them with short pulses. This offers exciting prospects for the realization of ultra-compact, integrated, scalable optical flip-flops based on spontaneous symmetry breaking. Furthermore, we predict such transitions with few intracavity photons for future devices with strong quantum correlations.

preprint2014arXivOpen access
Philippe HamelSamir HaddadiFabrice RaineriPaul MonnierGregoire BeaudoinIsabelle SagnesAriel LevensonAlejandro M. Yacomotti
cond-mat.mes-hallphysics.optics
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Philippe HamelSamir HaddadiFabrice RaineriPaul MonnierGregoire BeaudoinIsabelle SagnesAriel LevensonAlejandro M. Yacomotti

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