Optimization of the splice loss between photonic-bandgap fibers and conventional single-mode fibers

Aghaie, Kiarash Zamani; Digonnet, Michel J. F.; Fan, Shanhui

doi:10.1364/ol.35.001938

Cited by 37 publications

(23 citation statements)

References 6 publications

(16 reference statements)

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“…These compare with the lowest-reported loss of 0.9 dB for a splice between SMF-28 and bandgap-guiding HC-PCF [10]. For completeness, it is worth noting here that a loss of 0.79 dB between SMF with a mode field diameter optimized to match 7-cell PBG HC-PCF is reported in [31].…”

Section: Splice Characterisationsupporting

confidence: 62%

Large-core photonic microcells for coherent optics and laser metrology

et al. 2011

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A photonic microcell (PMC) is a length of gas-filled hollow core-photonic crystal fiber (HC-PCF) which is hermetically sealed at both ends by splicing to standard single mode fiber. We describe advances in the fabrication technique of PMCs which enable large core Kagome-lattice HC-PCFs to be integrated into PMC form. The modified fabrication technique uses fiber-tapering to accommodate the large dimensions of the fiber and enables low loss splices with single mode fiber by reducing mode field mismatch. Splice losses as low as 0.6 dB are achieved between 1-cell defect Kagome HC-PCF and single mode fiber. Relative to the previously reported PMCs, which were based on photonic bandgap HC-PCF, the present Kagome HC-PCF based PMC provides broad optical transmission, surface mode-free guidance and larger core at the cost of slightly increased fiber attenuation (~0.2 dB/m). Therefore, the integration of this fiber into PMC form opens up new applications for PMC-based devices. The advantage of the large core dimensions and surface mode free guidance for quantum optics in gas-filled HC-PCF are demonstrated by generation of narrow sub-Doppler features in an acetylenefilled large core PMC.

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Section: Splice Characterisationsupporting

confidence: 62%

Large-core photonic microcells for coherent optics and laser metrology

et al. 2011

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“…2 shows the superiority of the intermediate fiber method, which can reduce the coupling loss dramatically to 0.35 dB. It is generally believed the theoretical limit of the coupling loss is set by Fresnel reflection coefficient of 0.18 dB [10], [14]. Here we want to emphasize that the 0.18 dB (4%) Fresnel reflection mentioned frequently is measured at the normal incident angle.…”

Section: Coupling Loss Evaluationmentioning

confidence: 90%

Section: Coupling Loss Evaluationmentioning

confidence: 99%

“…We systematically investigate the splice loss between the HC-1550-02 fiber and the intermediate fiber by including the effects of mode size, mode shape and Fresnel reflection. It has been pointed out in [10] that the theoretical loss limit between the HC-1550-02 and a conventional SMF is 0.6 dB. To break this limit, we extend our research to cover multimode step-index fibers.…”

Section: Introductionmentioning

confidence: 99%

“…The reported fusion splice loss between two most widely used commercial fibers, i.e. NKT Photonics' 7-cell HC-1550-02 fiber and Corning's SMF28 fiber, keeps in Manuscript [10]. By replacing the SMF28 fiber with a more mode-matched fiber (Nufern's GF3), Aghaie et al [10] pushed this number down to 0.79 dB, representing the lowest splice loss record for 7-cell HC-PBGF.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Splice Loss Optimization of a Photonic Bandgap Fiber via a High V-Number Fiber

Gao

Tian

2014

IEEE Photon. Technol. Lett.

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We report on a low-loss fusion splice between a hollow-core photonic bandgap fiber (NKT's HC-1550-02) and a conventional single mode fiber (Corning's SMF28) using a high V-number intermediate fiber. Compared to the commonly used fiber postprocessing techniques, the intermediate fiber method offers a new adjusting degree of freedom of V-numbers, enabling the reduction of coupling loss to 0.35 dB. Experimentally, a low fusion splice loss of 0.63 dB has been achieved between Nufern's SM1950 (V = 2.836) and HC-1550-02 fiber, resulting in an overall insertion loss of 0.73 dB from SMF28 to HC-1550-02 fiber. We believe this is the lowest splice loss value reported for HC-1550-02 fiber using an arc splicer, on the aspect of both using a step-index solid-core fiber (0.63 dB) and a SMF28 fiber (0.73 dB).Index Terms-Hollow-core photonic bandgap fiber, splice loss, intermediate fiber, high V-number fiber.

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Coherent fiber supercontinuum for biophotonics

Boppart

2012

Laser & Photonics Reviews

116

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Biophotonics and nonlinear fiber optics have traditionally been two independent fields. Since the discovery of fiber-based supercontinuum generation in 1999, biophotonics applications employing incoherent light have experienced a large impact from nonlinear fiber optics, primarily because of the access to a wide range of wavelengths and a uniform spatial profile afforded by fiber supercontinuum. However, biophotonics applications employing coherent light have not benefited from the most well-known techniques of supercontinuum generation for reasons such as poor coherence (or high noise), insufficient controllability, and inadequate portability. Fortunately, a few key techniques involving nonlinear fiber optics and femtosecond laser development have emerged to overcome these critical limitations. Despite their relative independence, these techniques are the focus of this review, because they can be integrated into a low-cost portable biophotonics source platform. This platform can be shared across many different areas of research in biophotonics, enabling new applications such as point-of-care coherent optical biomedical imaging.

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Optimization of the splice loss between photonic-bandgap fibers and conventional single-mode fibers

Cited by 37 publications

References 6 publications

Large-core photonic microcells for coherent optics and laser metrology

Large-core photonic microcells for coherent optics and laser metrology

Splice Loss Optimization of a Photonic Bandgap Fiber via a High V-Number Fiber

Coherent fiber supercontinuum for biophotonics

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