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Chromium doped zinc selenide optical fiber lasers

Chromium doped zinc selenide optical fiber lasers
Chromium doped zinc selenide optical fiber lasers
The optical fiber geometry is known for rugged, high power laser sources that are preferred for many applications, but is typically limited to the visible and near-infrared regions of the electromagnetic spectrum due to the transmission limits of silica (< 2 µm). This wavelength range could be extended into the mid-infrared using transition metal doped, crystalline II-VI optical gain media, but these materials cannot be fabricated into optical fibers using conventional glass drawing methods. An in-situ high pressure chemical vapor deposition method for the fabrication of silica-cladded ZnSe fiber cores uniformly doped with Cr2+ is reported. Optical pumping experiments reveal that these doped fibers exhibit threshold behavior and thus function as mid-infrared optical fiber lasers. Finite element calculations show that undesirable thermal effects common in bulk II-VI crystals are mitigated in the fiber geometry.
2159-3930
1843-1852
Sparks, Justin R.
68cb6a0c-29ef-4487-8940-557b05b08568
Aro, Stephen C.
825c8f2d-901d-49ba-a538-6e156e54af3a
He, Rongrui
d89761c0-6ad3-460b-80a1-154d33763bdb
Goetz, Melanie L.
7ac659ae-b6f9-4d5c-8607-cda3b2885025
Krug, James P.
04a909be-6b7e-46a9-bb7b-65487d057346
McDaniel, Sean A.
1a6c4423-c63c-495d-8355-2f7d4f43d591
Berry, Patrick A.
e5746bfc-76b2-4362-b98c-a1b41cf4fa95
Cook, Gary
c33461e4-ea73-4b67-bdf8-9940f9c90f75
Schepler, Kenneth L.
006df834-ee4a-42c9-91bc-d037493cd43e
Sazio, Pier J.
0d6200b5-9947-469a-8e97-9147da8a7158
Gopalan, Venkatraman
c37ec093-614a-4b1c-a6ec-a5b32f398a58
Badding, John V.
dd484978-a8b8-4d1f-9b9e-b6b33bde9e7b
Sparks, Justin R.
68cb6a0c-29ef-4487-8940-557b05b08568
Aro, Stephen C.
825c8f2d-901d-49ba-a538-6e156e54af3a
He, Rongrui
d89761c0-6ad3-460b-80a1-154d33763bdb
Goetz, Melanie L.
7ac659ae-b6f9-4d5c-8607-cda3b2885025
Krug, James P.
04a909be-6b7e-46a9-bb7b-65487d057346
McDaniel, Sean A.
1a6c4423-c63c-495d-8355-2f7d4f43d591
Berry, Patrick A.
e5746bfc-76b2-4362-b98c-a1b41cf4fa95
Cook, Gary
c33461e4-ea73-4b67-bdf8-9940f9c90f75
Schepler, Kenneth L.
006df834-ee4a-42c9-91bc-d037493cd43e
Sazio, Pier J.
0d6200b5-9947-469a-8e97-9147da8a7158
Gopalan, Venkatraman
c37ec093-614a-4b1c-a6ec-a5b32f398a58
Badding, John V.
dd484978-a8b8-4d1f-9b9e-b6b33bde9e7b

Sparks, Justin R., Aro, Stephen C., He, Rongrui, Goetz, Melanie L., Krug, James P., McDaniel, Sean A., Berry, Patrick A., Cook, Gary, Schepler, Kenneth L., Sazio, Pier J., Gopalan, Venkatraman and Badding, John V. (2020) Chromium doped zinc selenide optical fiber lasers. Optical Materials Express, 10 (8), 1843-1852. (doi:10.1364/OME.397123).

Record type: Article

Abstract

The optical fiber geometry is known for rugged, high power laser sources that are preferred for many applications, but is typically limited to the visible and near-infrared regions of the electromagnetic spectrum due to the transmission limits of silica (< 2 µm). This wavelength range could be extended into the mid-infrared using transition metal doped, crystalline II-VI optical gain media, but these materials cannot be fabricated into optical fibers using conventional glass drawing methods. An in-situ high pressure chemical vapor deposition method for the fabrication of silica-cladded ZnSe fiber cores uniformly doped with Cr2+ is reported. Optical pumping experiments reveal that these doped fibers exhibit threshold behavior and thus function as mid-infrared optical fiber lasers. Finite element calculations show that undesirable thermal effects common in bulk II-VI crystals are mitigated in the fiber geometry.

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Accepted/In Press date: 18 June 2020
Published date: 16 July 2020
Additional Information: Funding information: Air Force Research Laboratory (FA8650-10-f-1902, FA8650-13-2-1615).
Learn more about Zepler Institute for Photonics and Nanoelectronics research

Identifiers

Local EPrints ID: 481373
URI: http://eprints.soton.ac.uk/id/eprint/481373
DOI: doi:10.1364/OME.397123
ISSN: 2159-3930
PURE UUID: 08bf2b78-3a0d-4370-9285-f5c7cc746394
ORCID for Pier J. Sazio: ORCID iD orcid.org/0000-0002-6506-9266

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Date deposited: 24 Aug 2023 16:40
Last modified: 18 Mar 2024 02:55

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Contributors

Author: Justin R. Sparks
Author: Stephen C. Aro
Author: Rongrui He
Author: Melanie L. Goetz
Author: James P. Krug
Author: Sean A. McDaniel
Author: Patrick A. Berry
Author: Gary Cook
Author: Kenneth L. Schepler
Author: Pier J. Sazio ORCID iD
Author: Venkatraman Gopalan
Author: John V. Badding

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