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Polarization maintaining single-mode low-loss hollow-core fibres

Author

Listed:
  • John M. Fini

    (OFS Laboratories)

  • Jeffrey W. Nicholson

    (OFS Laboratories)

  • Brian Mangan

    (OFS Laboratories)

  • Linli Meng

    (OFS Laboratories)

  • Robert S. Windeler

    (OFS Laboratories)

  • Eric M. Monberg

    (OFS Laboratories)

  • Anthony DeSantolo

    (OFS Laboratories)

  • Frank V. DiMarcello

    (OFS Laboratories)

  • Kazunori Mukasa

    (OFS Laboratories)

Abstract

Hollow-core fibre (HCF) is a powerful technology platform offering breakthrough performance improvements in sensing, communications, higher-power pulse delivery and other applications. Free from the usual constraints on what materials can guide light, it promises qualitatively new and ideal operating regimes: precision signals transmitted free of nonlinearities, sensors that guide light directly in the samples they are meant to probe and so on. However, these fibres have not been widely adopted, largely because uncontrolled coupling between transverse and polarization modes overshadows their benefits. To deliver on their promises, HCFs must retain their unique properties while achieving the modal and polarization control that are essential for their most compelling applications. Here we present the first single-moded, polarization-maintaining HCF with large core size needed for loss scaling. Single modedness is achieved using a novel scheme for resonantly coupling out unwanted modes, whereas birefringence is engineered by fabricating an asymmetrical glass web surrounding the core.

Suggested Citation

  • John M. Fini & Jeffrey W. Nicholson & Brian Mangan & Linli Meng & Robert S. Windeler & Eric M. Monberg & Anthony DeSantolo & Frank V. DiMarcello & Kazunori Mukasa, 2014. "Polarization maintaining single-mode low-loss hollow-core fibres," Nature Communications, Nature, vol. 5(1), pages 1-7, December.
    • Handle: RePEc:nat:natcom:v:5:y:2014:i:1:d:10.1038_ncomms6085
    DOI: 10.1038/ncomms6085
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    Cited by:

    1. Maochun Li & Yizhi Sun & Shoufei Gao & Xiaoming Zhao & Fei Hui & Wei Luo & Qingbo Hu & Hao Chen & Helin Wu & Yingying Wang & Miao Yan & Wei Ding, 2025. "Navigation-grade interferometric air-core antiresonant fibre optic gyroscope with enhanced thermal stability," Nature Communications, Nature, vol. 16(1), pages 1-12, December.

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