Research

Photonic Crystal Fibres for Coherent Supercontinuum Generation


Reference:

Hooper, L., 2012. Photonic Crystal Fibres for Coherent Supercontinuum Generation. Thesis (Doctor of Philosophy (PhD)). University of Bath.

Related documents:

[img]
Preview
PDF (Thesis) - Requires a PDF viewer such as GSview, Xpdf or Adobe Acrobat Reader
Download (5MB) | Preview

    Abstract

    Inthisresearchphotoniccrystalfibresweredevelopedforthepurposeofgeneratingcoherent supercontinua. Two photonic crystal fibres were fabricated with all-normal group velocity dispersionprofiles, withlow dispersion atpump wavelengths 800 nm and 1064 nm. Supercontinua generatedusing these fibreswereshowntohavesuperiorstability and coherencecompared with supercontinua generated in fibres with anomalous dispersion at the pump wavelength. Using a short piece of photonic crystal fibre with all-normal group velocity dispersion, pumped at 1064 nm, a self phase modulation spectrum spanning 200 nm was generated. The supercontinuum was re-compressed using linear chirp compensation to 26 fs, which was within a factor of two of the theoretical transform limit. This demonstrates the high spectral coherence, stability, and almost-linear chirp of the supercontinuum. Simulations showed that pulse compressionusing asupercontinuumgeneratedinaphotoniccrystal fibrewith anomalousdispersion at the pump wavelength would be limited by shot-to-shot fluctuations in the spectral intensity and phase, and the nonlinear chirp. Using alongerpieceof all-normaldispersionphotoniccrystal fibre,supercontinuumisgenerated by self phase modulation, and optical wave breaking. A broad flat supercontinuum spanning 700 nm, centred at 1064 nm was generated. This supercontinuum was spectrally filtered, and the pulses obtained analysed in the temporal domain. Clean, stable sub-picosecond pulses were achieved, demonstrating the applicability of such a supercontinuum as part of a compact, tunable laser source. The same experiment was carried out using a photonic crystal fibre with anomalous dispersion at the pump wavelength, resulting in pulses with a large portion of energy contained in broad shoulders, and higher order modes. Interferometric coherence measurements were carried out at 800 nm using a Ti:Sapphire laser. A supercontinuum was generated in all-normal dispersion photonic crystal fibre with low dispersion at 800 nm, spanning 400 nm. Supercontinuum pulses generated by consecutive laser pulses were brought together in time using an interferometer. The interference between consecutive pulses was viewed spectrally, and the interference fringes had high visibility across the whole supercontinuumbandwidth. Thisdemonstrateshighspectral coherence. Asupercontinuum generated in photonic crystal fibre with anomalous dispersion at 800 nm was tested in the same way, and the interference fringes obtained had lower visibility, indicating low spectral coherence. Theresearchpresenteddemonstratesthatphotoniccrystal fibreswith all-normaldispersion profiles can be used togenerate supercontinua withhigh coherence and intensity stability. This type of supercontinuum is applicable to ultra-short pulse compression, and can be spectrally filtered to create a broadband tunable ultra-short laser source.

    Details

    Item Type Thesis (Doctor of Philosophy (PhD))
    CreatorsHooper, L.
    Uncontrolled Keywordsphotonic crystal fibres, supercontinuum, coherence
    DepartmentsFaculty of Science > Physics
    Publisher StatementUnivBath_PhD_2012_L_Hooper.pdf: © The Author
    StatusUnpublished
    ID Code31806

    Export

    Actions (login required)

    View Item

    Document Downloads

    More statistics for this item...