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Low-loss splicing between anti-reflection coated SMF and hollow-core fiber without back-reflection degradation

Low-loss splicing between anti-reflection coated SMF and hollow-core fiber without back-reflection degradation
Low-loss splicing between anti-reflection coated SMF and hollow-core fiber without back-reflection degradation
Anti-reflection (AR) coating is an effective technique for reducing back-reflection and insertion loss (IL) in the interconnection between standard single-mode fiber (SSMF) and hollow-core fiber (HCF). However, the difference in thermal expansion coefficient between the fiber and coating leads to performance degradation during fusion splicing. To address this limitation, we report an embedded fiber splicing technique that uses a tapered borosilicate glass tube (BGT) as a splicing bridge, thereby avoiding direct heating of the AR coating. Theoretical analysis shows that a minimal IL of 0.13 dB can be achieved by optimizing the structural parameters, including the GRIN length and the air-cavity length, when the HCF mode field diameter ranges from 17 to 21 μm. Then, the SSMF with an AR-coated GRIN end is inserted into a tapered BGT, with the untapered side spliced to the HCF. By managing the GRIN length, the air gap, and the splicing offset, a low-IL interconnection can be achieved without the back-reflection penalty. Finally, an SSMF-HCF-SSMF interconnection link with an IL of 0.6 dB and a back-reflection of −33.8 dB is experimentally achieved. Meanwhile, higher-order mode coupling is well suppressed to below −35 dB. The proposed embedded splicing technique can facilitate HCF applications in a harsh environment.
0146-9592
193-196
Zhang, Cong
2425f04c-27c2-49e4-baeb-05c324a0d133
Chen, Jiajie
fd731d69-cb88-4c50-8646-7f4707057ad3
Li, Jianping
a302e2eb-131f-4363-9fb6-16502cf4eac7
Xiang, Meng
262b5317-ac04-4a27-92ca-b450397bc4b0
Qin, Yuwen
cfe04c76-c8e4-4124-8a21-3e645172c915
Slavík, Radan
2591726a-ecc0-4d1a-8e1d-4d0fd8da8f7d
Fu, Songnian
c07e2c14-6ae0-4ec3-b09a-8d3800763d66
Zhang, Cong
2425f04c-27c2-49e4-baeb-05c324a0d133
Chen, Jiajie
fd731d69-cb88-4c50-8646-7f4707057ad3
Li, Jianping
a302e2eb-131f-4363-9fb6-16502cf4eac7
Xiang, Meng
262b5317-ac04-4a27-92ca-b450397bc4b0
Qin, Yuwen
cfe04c76-c8e4-4124-8a21-3e645172c915
Slavík, Radan
2591726a-ecc0-4d1a-8e1d-4d0fd8da8f7d
Fu, Songnian
c07e2c14-6ae0-4ec3-b09a-8d3800763d66

Zhang, Cong, Chen, Jiajie, Li, Jianping, Xiang, Meng, Qin, Yuwen, Slavík, Radan and Fu, Songnian (2025) Low-loss splicing between anti-reflection coated SMF and hollow-core fiber without back-reflection degradation. Optics Letters, 51 (1), 193-196. (doi:10.1364/OL.583364).

Record type: Article

Abstract

Anti-reflection (AR) coating is an effective technique for reducing back-reflection and insertion loss (IL) in the interconnection between standard single-mode fiber (SSMF) and hollow-core fiber (HCF). However, the difference in thermal expansion coefficient between the fiber and coating leads to performance degradation during fusion splicing. To address this limitation, we report an embedded fiber splicing technique that uses a tapered borosilicate glass tube (BGT) as a splicing bridge, thereby avoiding direct heating of the AR coating. Theoretical analysis shows that a minimal IL of 0.13 dB can be achieved by optimizing the structural parameters, including the GRIN length and the air-cavity length, when the HCF mode field diameter ranges from 17 to 21 μm. Then, the SSMF with an AR-coated GRIN end is inserted into a tapered BGT, with the untapered side spliced to the HCF. By managing the GRIN length, the air gap, and the splicing offset, a low-IL interconnection can be achieved without the back-reflection penalty. Finally, an SSMF-HCF-SSMF interconnection link with an IL of 0.6 dB and a back-reflection of −33.8 dB is experimentally achieved. Meanwhile, higher-order mode coupling is well suppressed to below −35 dB. The proposed embedded splicing technique can facilitate HCF applications in a harsh environment.

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Accepted/In Press date: 10 December 2025
e-pub ahead of print date: 23 December 2025

Identifiers

Local EPrints ID: 509537
URI: http://eprints.soton.ac.uk/id/eprint/509537
DOI: doi:10.1364/OL.583364
ISSN: 0146-9592
PURE UUID: 34395707-c26e-48b0-b216-6b23f7dd331a
ORCID for Radan Slavík: ORCID iD orcid.org/0000-0002-9336-4262

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Date deposited: 25 Feb 2026 17:42
Last modified: 26 Feb 2026 02:42

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Contributors

Author: Cong Zhang
Author: Jiajie Chen
Author: Jianping Li
Author: Meng Xiang
Author: Yuwen Qin
Author: Radan Slavík ORCID iD
Author: Songnian Fu

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