Designing the properties of dispersion-flattened photonic crystal fibers

Ferrando, Albert; Silvestre, Enrique; Andrés, Pedro; Miret, Juan Jose; Andrés, Miguel V.

doi:10.1364/oe.9.000687

Cited by 295 publications

(139 citation statements)

References 8 publications

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“…However, since the pump wavelength is closer to the ZDW of the material, dispersion flattened fibers should be possible, and we might expect significantly more broadening using optimised dispersion design algorithms previously developed for silica-based MOF fabrication 46 to develop suitable fiber structures for compound glasses. Since the material damage thresholds of the glasses are not yet well understood, reducing the threshold peak intensity required for continuum generation could be an important practical consideration.…”

Section: Discussionmentioning

confidence: 99%

Non-silica microstructured optical fibers for mid-IR supercontinuum generation from 2 μm - 5 μm

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Ebendorff-Heidepriem

et al. 2006

Fiber Lasers III: Technology, Systems, and Applications

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We have performed numerical simulations to investigate the optimization of compound glass microstructured optical fibers for mid IR supercontinuum generation beyond the low loss transmission window of silica, using pump wavelengths in the range 1.55-2.25 µm. Large mode area fibers for high powers, and small core fiber designs for low powers, are proposed for a variety of glasses. Modeling results showed that for Bismuth and lead oxide glasses, which have nonlinearities ~10 x that of silica, matching the dispersion profile to the pump wavelength is essential. For chalcogenide glasses, which have much higher nonlinearities, the dispersion profile is less important. The pump pulses have duration of <1 ps, and energy <30 nJ. The fiber lengths required for generating continuum were <40 mm, so the losses of the fibers were not a limiting factor. Compared to planar rib-waveguides or fiber-tapers, microstructured fiber technology has the advantages of greater flexibility for tailoring the dispersion profile over a broad wavelength span, and a much wider possible range of device lengths.

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Section: Discussionmentioning

confidence: 99%

Non-silica microstructured optical fibers for mid-IR supercontinuum generation from 2 μm - 5 μm

Price

Monro

Ebendorff-Heidepriem

et al. 2006

Fiber Lasers III: Technology, Systems, and Applications

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“…5(a) In order to analyze the dispersion properties of PQFs based in the Thue-Morse sequence, we have simulated a number of different direct and inverse designs by changing the equivalent quasiperiod, Λ, the hole radius of the aperiodic lattice, a, and the hole radius of the defects, b. In this way, by analyzing the dispersion curves of these different PQFs, we have found that it is possible to control their dispersion characteristics following a procedure similar to that described in [28]. The group velocity dispersion, D, including the material dispersion, can be evaluated as…”

Section: Guiding and Dispersion Propertiesmentioning

confidence: 99%

Guiding Properties of a Photonic Quasi-Crystal Fiber Based on the Thue–Morse Sequence

Ferrando

Coves

Andrés

et al. 2015

IEEE Photon. Technol. Lett.

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“…Hydrostatic pressure sensors based on birefringent fibers are not compact since they usually need non-fiber components to detect the pressure-induced phase or use the fiber Sagnac interferometer with a relatively long sensing fiber. PCFs [28][29][30][31][32] are the great success in the history of optical fibers, which have achieved excellent properties in birefringence [33][34][35][36][37][38][39][40], dispersion [41][42][43][44][45][46][47][48][49][50][51], single polarization single mode [52][53][54], nonlinearity [55], and effective mode area [56][57][58], and also excellent performances in the applications of fiber lasers [59][60][61] and nonlinear optics [62][63][64][65] over the past several years. PCFs have also further improved optical fiber sensors and have been used for strain sensing [66], gas sensing [67], biochemical sensing [68], refractive index sensing [69] and temperature sensing [70].…”

Section: Introductionmentioning

confidence: 99%

Hydrostatic Pressure Sensor Based on a Gold-Coated Fiber Modal Interferometer Using Lateral Offset Splicing of Single Mode Fiber

Chen¹,

Cheng²

2012

PIER

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Abstract-A novel hydrostatic pressure sensor based on a gold-coated fiber modal interferometer (FMI) is proposed and demonstrated. Two single mode fibers (SMFs) are spliced with a lateral offset which forms a single-end FMI. The single-end FMI is gold-coated to enhance the reflectivity and to avoid the influence of any unwanted light from getting into the sensor. Relative reflection spectra of the proposed FMIs with different sensing SMF lengths or different lateral offsets are experimentally investigated. A high hydrostatic pressure sensor test system is proposed for the testing of the proposed FMI pressure sensor. The performance of a gold-coated FMI pressure sensor based on a 12-mm sensing SMF has been experimentally investigated. The proposed pressure sensor has a sensing range from 0 to 42 MPa and a sensitivity of 53 pm/MPa.

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Designing the properties of dispersion-flattened photonic crystal fibers

Cited by 295 publications

References 8 publications

Non-silica microstructured optical fibers for mid-IR supercontinuum generation from 2 μm - 5 μm

Non-silica microstructured optical fibers for mid-IR supercontinuum generation from 2 μm - 5 μm

Guiding Properties of a Photonic Quasi-Crystal Fiber Based on the Thue–Morse Sequence

Hydrostatic Pressure Sensor Based on a Gold-Coated Fiber Modal Interferometer Using Lateral Offset Splicing of Single Mode Fiber

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