H. Sabert scite author profile

Hollow-core photonic crystal fibres have excited interest as potential ultra-low loss telecommunications fibres because light propagates mainly in air instead of solid glass. We propose that the ultimate limit to the attenuation of such fibres is determined by surface roughness due to frozenin capillary waves. This is confirmed by measurements of the surface roughness in a HC-PCF, the angular distribution of the power scattered out of the core, and the wavelength dependence of the minimum loss of fibres drawn to different scales.

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Properties of a hollow-core photonic bandgap fiber at 850 nm wavelength

Bouwmans¹,

Luan²,

Knight³

et al. 2003

Opt. Express

129

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We describe a hollow-core photonic bandgap fiber designed for use in the 850 nm wavelength region. The fiber has a minimum attenuation of 180dB/km at 847nm wavelength. The low-loss mode has a quasi- Gaussian intensity profile. The group-velocity dispersion of this mode passes through zero around 830nm, and is anomalous for longer wavelengths. The polarization beat length varies from 4 mm to 13 mm across the band gap. We expect this fiber to be useful for delivery of high-energy ultrashort optical pulses.

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Pulse generation in fiber lasers with frequency shifted feedback

Sabert

Brinkmeyer

1994

J. Lightwave Technol.

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Realizing low loss air core photonic crystal fibers by exploiting an antiresonant core surround

Roberts

Williams

Mangan³

et al. 2005

Opt. Express

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The modal properties of an air core photonic crystal fiber which incorporates an anti-resonant feature within the region that marks the transition between the air core and the crystal cladding are numerically calculated. The field intensity at the glass/air interfaces is shown to be reduced by a factor of approximately three compared to a fiber with more conventional core surround geometry. The reduced interface field intensity comes at the expense of an increased number of unwanted core interface modes within the band gap. When the interface field intensity is associated with modal propagation loss, the findings are in accord with recent measurements on fabricated fibers which incorporate a similar antiresonant feature.

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H. Sabert

Ultimate low loss of hollow-core photonic crystal fibres

Properties of a hollow-core photonic bandgap fiber at 850 nm wavelength

Pulse generation in fiber lasers with frequency shifted feedback

Realizing low loss air core photonic crystal fibers by exploiting an antiresonant core surround

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