Maximizing the bandwidth of coherent, mid-IR supercontinuum using highly nonlinear aperiodic nanofibers
Maximizing the bandwidth of coherent, mid-IR supercontinuum using highly nonlinear aperiodic nanofibers
We describe in detail a new procedure of maximizing the bandwidth of mid-infrared (mid-IR) supercontinuum (SC) in highly nonlinear microstructured As2Se3 and tellurite aperiodic nanofibers. By introducing aperiodic rings of first and secondary air holes into the cross-sections of our microstructured fiber designs, we achieve flattened and all-normal dispersion profiles over much broader bandwidths than would be possible with simple periodic designs. These fiber designs are optimized for efficient, broadband, and coherent SC generation in the mid-IR spectral region. Numerical simulations show that these designs enable the generation of a SC spanning over 2290 nm extending from 1140 to 3430 nm in 8 cm length of tellurite nanofiber with input energy of E = 200 pJ and a SC bandwidth of over 4700 nm extending from 1795 to 6525 nm generated in only 8 mm-length of As2Se3-based nanofiber with input energy as low as E = 100 pJ. This work provides a new type of broadband mid-IR SC source with flat spectral shape as well as excellent coherence and temporal properties by using aperiodic nanofibers with all-normal dispersion suitable for applications in ultrafast science, metrology, coherent control, non-destructive testing, spectroscopy, and optical coherence tomography in the mid-IR region.
650-661
Baili, Amira
8a713be8-5e71-4607-9508-9f8af324400c
Cherif, Rim
07a1b64f-7575-4f00-aa64-22ca11283e68
Heidt, Alexander
18f56d74-848c-420c-9ece-715e3e94e97a
Zghal, Mourad
08a38b7b-afe3-4641-b399-6a687d2d7064
2014
Baili, Amira
8a713be8-5e71-4607-9508-9f8af324400c
Cherif, Rim
07a1b64f-7575-4f00-aa64-22ca11283e68
Heidt, Alexander
18f56d74-848c-420c-9ece-715e3e94e97a
Zghal, Mourad
08a38b7b-afe3-4641-b399-6a687d2d7064
Baili, Amira, Cherif, Rim, Heidt, Alexander and Zghal, Mourad
(2014)
Maximizing the bandwidth of coherent, mid-IR supercontinuum using highly nonlinear aperiodic nanofibers.
Journal of Modern Optics, 61 (8), .
(doi:10.1080/09500340.2014.905646).
Abstract
We describe in detail a new procedure of maximizing the bandwidth of mid-infrared (mid-IR) supercontinuum (SC) in highly nonlinear microstructured As2Se3 and tellurite aperiodic nanofibers. By introducing aperiodic rings of first and secondary air holes into the cross-sections of our microstructured fiber designs, we achieve flattened and all-normal dispersion profiles over much broader bandwidths than would be possible with simple periodic designs. These fiber designs are optimized for efficient, broadband, and coherent SC generation in the mid-IR spectral region. Numerical simulations show that these designs enable the generation of a SC spanning over 2290 nm extending from 1140 to 3430 nm in 8 cm length of tellurite nanofiber with input energy of E = 200 pJ and a SC bandwidth of over 4700 nm extending from 1795 to 6525 nm generated in only 8 mm-length of As2Se3-based nanofiber with input energy as low as E = 100 pJ. This work provides a new type of broadband mid-IR SC source with flat spectral shape as well as excellent coherence and temporal properties by using aperiodic nanofibers with all-normal dispersion suitable for applications in ultrafast science, metrology, coherent control, non-destructive testing, spectroscopy, and optical coherence tomography in the mid-IR region.
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Published date: 2014
Organisations:
Optoelectronics Research Centre
Identifiers
Local EPrints ID: 365887
URI: http://eprints.soton.ac.uk/id/eprint/365887
ISSN: 0950-0340
PURE UUID: a96080ba-f883-4673-bdb4-3b8e6800ecab
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Date deposited: 20 Jun 2014 12:57
Last modified: 14 Mar 2024 17:02
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Contributors
Author:
Amira Baili
Author:
Rim Cherif
Author:
Alexander Heidt
Author:
Mourad Zghal
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