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Giant Enhancement of Magnonic Frequency Combs by Exceptional Points

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arxiv 2306.02120 v1 pith:IOBLONQA submitted 2023-06-03 cond-mat.mes-hall physics.optics

Giant Enhancement of Magnonic Frequency Combs by Exceptional Points

classification cond-mat.mes-hall physics.optics
keywords frequencycombsmagnonicmfcsnonlinearpowerdetectionexceptional
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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With their incomparable time-frequency accuracy, frequency combs have significantly advanced precision spectroscopy, ultra-sensitive detection, and atomic clocks. Traditional methods to create photonic, phononic, and magnonic frequency combs hinge on material nonlinearities which are often weak, necessitating high power densities to surpass their initiation thresholds, which subsequently limits their applications. Here, we introduce a novel nonlinear process to efficiently generate magnonic frequency combs (MFCs) by exploiting exceptional points (EPs) in a coupled system comprising a pump-induced magnon mode and a Kittel mode. Even without any cavity, our method greatly improves the efficiency of nonlinear frequency conversion and achieves optimal MFCs at low pump power. Additionally, our novel nonlinear process enables excellent tunability of EPs using the polarization and power of the pump, simplifying MFC generation and manipulation. Our work establishes a synergistic relationship between non-Hermitian physics and MFCs, which is advantages for coherent/quantum information processing and ultra-sensitive detection.

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