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Reduced loss and bend sensitivity in hermetically-sealed hollow-core fiber gas cells using gas-induced differential refractive index

Reduced loss and bend sensitivity in hermetically-sealed hollow-core fiber gas cells using gas-induced differential refractive index
Reduced loss and bend sensitivity in hermetically-sealed hollow-core fiber gas cells using gas-induced differential refractive index

Hollow-core optical fiber (HCF) gas cells are an attractive option for many applications including metrology and non-linear optics due to the enhanced gas-light interaction length in a compact and lightweight format. Here, we report the first demonstration and characterization of a selectively pressurized, hermetically sealed hollow-core fiber-based gas cell, where the core is filled with a higher gas pressure than the cladding to enhance the optical performance. This differential gas pressure creates a gas-induced differential refractive index (GDRI) that is shown to enable significant modification of the HCF’s optical performance. Measurements on fabricated gas cells indicate a significant broadband reduction in attenuation of up to ∼10 dB (at 1100 nm) for a 24 m fiber length and an estimated pressure difference of ∼6 bar between the gas in the core and cladding regions. Additionally, using the fabricated gas cells, we show experimentally for the first time that GDRI can reduce macrobend loss in HCFs. Finally, long term (one year) measurements indicate no degradation in the gas cell performance due to gas permeation or gas exchange between the core and cladding regions, demonstrating the viability of using this gas cell format to implement a GDRI within a HCF to improve optical performance over an extended time period in an all-fiber format.

1094-4087
885-896
Pradhan, Somarpita
49acdab1-62de-409d-8ecf-8d211bbadace
Kelly, Thomas W.
64bf9b49-b287-4d23-8809-a2627f8d4bf2
Elistratova, Elizaveta
5b5fd0c8-9c2f-4768-9aaa-f611c0396ac5
Davidson, Ian A.
b685f949-e9e4-4e6b-9a59-36739de06a61
Horak, Peter
520489b5-ccc7-4d29-bb30-c1e36436ea03
Wheeler, Natalie V.
0fd34178-a77b-4c71-a3a6-86a1f634f1a0
Pradhan, Somarpita
49acdab1-62de-409d-8ecf-8d211bbadace
Kelly, Thomas W.
64bf9b49-b287-4d23-8809-a2627f8d4bf2
Elistratova, Elizaveta
5b5fd0c8-9c2f-4768-9aaa-f611c0396ac5
Davidson, Ian A.
b685f949-e9e4-4e6b-9a59-36739de06a61
Horak, Peter
520489b5-ccc7-4d29-bb30-c1e36436ea03
Wheeler, Natalie V.
0fd34178-a77b-4c71-a3a6-86a1f634f1a0

Pradhan, Somarpita, Kelly, Thomas W., Elistratova, Elizaveta, Davidson, Ian A., Horak, Peter and Wheeler, Natalie V. (2025) Reduced loss and bend sensitivity in hermetically-sealed hollow-core fiber gas cells using gas-induced differential refractive index. Optics Express, 33 (1), 885-896. (doi:10.1364/OE.545939).

Record type: Article

Abstract

Hollow-core optical fiber (HCF) gas cells are an attractive option for many applications including metrology and non-linear optics due to the enhanced gas-light interaction length in a compact and lightweight format. Here, we report the first demonstration and characterization of a selectively pressurized, hermetically sealed hollow-core fiber-based gas cell, where the core is filled with a higher gas pressure than the cladding to enhance the optical performance. This differential gas pressure creates a gas-induced differential refractive index (GDRI) that is shown to enable significant modification of the HCF’s optical performance. Measurements on fabricated gas cells indicate a significant broadband reduction in attenuation of up to ∼10 dB (at 1100 nm) for a 24 m fiber length and an estimated pressure difference of ∼6 bar between the gas in the core and cladding regions. Additionally, using the fabricated gas cells, we show experimentally for the first time that GDRI can reduce macrobend loss in HCFs. Finally, long term (one year) measurements indicate no degradation in the gas cell performance due to gas permeation or gas exchange between the core and cladding regions, demonstrating the viability of using this gas cell format to implement a GDRI within a HCF to improve optical performance over an extended time period in an all-fiber format.

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More information

Submitted date: 31 October 2024
Accepted/In Press date: 18 December 2024
Published date: 7 January 2025

Identifiers

Local EPrints ID: 501956
URI: http://eprints.soton.ac.uk/id/eprint/501956
DOI: doi:10.1364/OE.545939
ISSN: 1094-4087
PURE UUID: c7ba9c35-4f04-4a47-9f34-2f4c334528a0
ORCID for Peter Horak: ORCID iD orcid.org/0000-0002-8710-8764
ORCID for Natalie V. Wheeler: ORCID iD orcid.org/0000-0002-1265-9510

Catalogue record

Date deposited: 12 Jun 2025 16:59
Last modified: 22 Aug 2025 02:04

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Contributors

Author: Somarpita Pradhan
Author: Thomas W. Kelly
Author: Elizaveta Elistratova
Author: Ian A. Davidson
Author: Peter Horak ORCID iD
Author: Natalie V. Wheeler ORCID iD

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