D. Müller scite author profile

Photonic bandgap structures use the principle of interference to reflect radiation. Reflection from photonic bandgap structures has been demonstrated in one, two and three dimensions and various applications have been proposed. Early work in hollow-core photonic bandgap fibre technology used a hexagonal structure surrounding the air core; this fibre was the first demonstration of light guided inside an air core of a photonic bandgap fibre. The potential benefits of guiding light in air derive from lower Rayleigh scattering, lower nonlinearity and lower transmission loss compared to conventional waveguides. In addition, these fibres offer a new platform for studying nonlinear optics in gases. Owing largely to challenges in fabrication, the early air-core fibres were only available in short lengths, and so systematic studies of loss were not possible. More recently, longer lengths of fibre have become available with reported losses of 1,000 dB km(-1). We report here the fabrication and characterization of long lengths of low attenuation photonic bandgap fibre. Attenuation of less than 30 dB km(-1) over a wide transmission window is observed with minimum loss of 13 dB km(-1) at 1,500 nm, measured on 100 m of fibre. Coupling between surface and core modes of the structure is identified as an important contributor to transmission loss in hollow-core photonic bandgap fibres.

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Generation of Megawatt Optical Solitons in Hollow-Core Photonic Band-Gap Fibers

Ouzounov

Ahmad

Müller

et al. 2003

Science

466

186

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The measured dispersion of a low-loss, hollow-core photonic band-gap fiber is anomalous throughout most of the transmission band, and its variation with wavelength is large compared with that of a conventional step-index fiber. For an air-filled fiber, femtosecond self-frequency--shifted fundamental solitons with peak powers greater than 2megawatts can be supported. For Xe-filled fibers, nonfrequency-shifted temporal solitons with peak powers greater than 5.5 megawatts can be generated, representing an increase in the power that can be propagated in an optical fiber of two orders of magnitude. The results demonstrate a unique capability to deliver high-power pulses in a single spatial mode over distances exceeding 200 meters.

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High-resolution solid-state 27Al and 31P NMR: correlation between chemical shift and mean Al-O-P angle in AlPO4 polymorphs

Müller¹,

Jahn²,

Ladwig³

et al. 1984

Chemical Physics Letters

257

140

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Structure and Catalytic Properties of VO /MCM Materials for the Partial Oxidation of Methane to Formaldehyde

Berndt

Martin

Brückner

et al. 2000

Journal of Catalysis

244

119

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D. Müller

Low-loss hollow-core silica/air photonic bandgap fibre

Generation of Megawatt Optical Solitons in Hollow-Core Photonic Band-Gap Fibers

High-resolution solid-state 27Al and 31P NMR: correlation between chemical shift and mean Al-O-P angle in AlPO4 polymorphs

Structure and Catalytic Properties of VO /MCM Materials for the Partial Oxidation of Methane to Formaldehyde

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