2016
DOI: 10.1364/ol.42.000085
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Fiber ring resonator with a nanofiber section for chiral cavity quantum electrodynamics and multimode strong coupling

Abstract: We experimentally realize an optical fiber ring resonator that includes a tapered section with subwavelength-diameter waist. In this section, the guided light exhibits a significant evanescent field which allows for efficient interfacing with optical emitters. A commercial tunable fiber beam splitter provides simple and robust coupling to the resonator. Key parameters of the resonator such as its out-coupling rate, free spectral range, and birefringence can be adjusted. Thanks to the low taperand coupling-loss… Show more

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Cited by 47 publications
(32 citation statements)
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“…For example, the nanofiber cavity with two fiber Bragg gratings [19] has a mode volume of about 2.6×10 4 μm 3 . The nanofiber cavity with fiber beam splitter gives a big mode volume according to the cavity length of more than two meters [20]. The nanofiber Bragg cavity has the smallest mode volume among the achieved methods for nanofiber based cavity [14], the mode volume is 1 μm 3 , which is achieved with a fabrication process far more demanding than ours.…”
Section: Introductionmentioning
confidence: 79%
“…For example, the nanofiber cavity with two fiber Bragg gratings [19] has a mode volume of about 2.6×10 4 μm 3 . The nanofiber cavity with fiber beam splitter gives a big mode volume according to the cavity length of more than two meters [20]. The nanofiber Bragg cavity has the smallest mode volume among the achieved methods for nanofiber based cavity [14], the mode volume is 1 μm 3 , which is achieved with a fabrication process far more demanding than ours.…”
Section: Introductionmentioning
confidence: 79%
“…just like in figure 2, the unguided modes remove the pure dimerized steady state, which now is probed dynamically through fluctuations, like in the homogeneous detuning scenario. Finally we remark, that the coupling strength between the quantum emitters and the guided modes can be controlled by employing a cavity, as showed in [40], or by considering a photonic crystal waveguide integrated with solid-state emitters, as shown in [41]. Here, the chiral interaction is obtained in presence of slow-light, together with a strong Purcell enhancement.…”
Section: Emission Into Unguided Modesmentioning
confidence: 92%
“…The ability to interface quantum emitters with optical systems opens novel routes for investigating nonequilibrium phenomena in open condensed matter physics [1] and provides, potentially, a platform to perform quantum information processing [2][3][4][5][6][7]. In recent years, the open quantum dynamics of chiral systems, where the emission of photons into a waveguide presents a broken left-right symmetry, has been the object of intense investigation [8][9][10][11][12][13][14][15]. This propagation-direction-dependent light-matter interaction has been observed in a variety of systems, for instance atoms coupled to the evanescent field of a waveguide [16] or a photonic crystal [17][18][19], and quantum dots in photonic nano-structures [20].…”
Section: Introductionmentioning
confidence: 99%
“…On the other hand, atoms are naturally identical quantum emitters so the system composed of these quantum emitters combined with nano-photonic devices would substantially improve the inhomogeneous broadening of these hybrid systems 21,22 . Therefore, the hybrid quantum systems of atoms and nano-photonic devices have a promising perspective for exploring new realms of CQED.…”
Section: Introductionmentioning
confidence: 99%