Standard

Narrow-band fibre reflector based on a fibre Bragg grating reflection interferometer. / Terentyev, V. S.; Vlasov, A. A.; Abdullina, S. R. et al.

In: Quantum Electronics, Vol. 48, No. 8, 01.01.2018, p. 728-732.

Research output: Contribution to journalArticlepeer-review

Harvard

Terentyev, VS, Vlasov, AA, Abdullina, SR, Simonov, VA, Skvortsov, MI & Babin, SA 2018, 'Narrow-band fibre reflector based on a fibre Bragg grating reflection interferometer', Quantum Electronics, vol. 48, no. 8, pp. 728-732. https://doi.org/10.1070/QEL16695

APA

Terentyev, V. S., Vlasov, A. A., Abdullina, S. R., Simonov, V. A., Skvortsov, M. I., & Babin, S. A. (2018). Narrow-band fibre reflector based on a fibre Bragg grating reflection interferometer. Quantum Electronics, 48(8), 728-732. https://doi.org/10.1070/QEL16695

Vancouver

Terentyev VS, Vlasov AA, Abdullina SR, Simonov VA, Skvortsov MI, Babin SA. Narrow-band fibre reflector based on a fibre Bragg grating reflection interferometer. Quantum Electronics. 2018 Jan 1;48(8):728-732. doi: 10.1070/QEL16695

Author

Terentyev, V. S. ; Vlasov, A. A. ; Abdullina, S. R. et al. / Narrow-band fibre reflector based on a fibre Bragg grating reflection interferometer. In: Quantum Electronics. 2018 ; Vol. 48, No. 8. pp. 728-732.

BibTeX

@article{ae2a434de2e44fabb8b73394e5f797db,
title = "Narrow-band fibre reflector based on a fibre Bragg grating reflection interferometer",
abstract = "Narrow-band filtering in reflected light using a reflection interferometer with a fibre Bragg grating (FBG) as its back mirror is demonstrated for the first time. The reflection interferometer is made in SMF-28e single-mode fibre, and the faces of its front mirror, which includes a thin metallic film, differ in reflectance. The reflection bandwidth of a test sample is 0.5 pm (62 MHz) at a wavelength of 1556 nm (Q-factor of 3 ´ 10 6), its maximum reflectance is 0.21, and its contrast is 10 2. The use of a narrow-band FBG instead of thin-film broadband mirrors allows spectral selection to be significantly improved owing to an increase in the length of the interferometer base.",
keywords = "Dielectric interference coating, Fibre Bragg grating, Fibre optics, Multiple-beam interference, Reflection interferometer, Thin metallic film, fibre optics, LASER, LIGHT, thin metallic film, multiple-beam interference, reflection interferometer, dielectric interference coating, fibre Bragg grating",
author = "Terentyev, {V. S.} and Vlasov, {A. A.} and Abdullina, {S. R.} and Simonov, {V. A.} and Skvortsov, {M. I.} and Babin, {S. A.}",
year = "2018",
month = jan,
day = "1",
doi = "10.1070/QEL16695",
language = "English",
volume = "48",
pages = "728--732",
journal = "Quantum Electronics",
issn = "1063-7818",
publisher = "Turpion Ltd.",
number = "8",

}

RIS

TY - JOUR

T1 - Narrow-band fibre reflector based on a fibre Bragg grating reflection interferometer

AU - Terentyev, V. S.

AU - Vlasov, A. A.

AU - Abdullina, S. R.

AU - Simonov, V. A.

AU - Skvortsov, M. I.

AU - Babin, S. A.

PY - 2018/1/1

Y1 - 2018/1/1

N2 - Narrow-band filtering in reflected light using a reflection interferometer with a fibre Bragg grating (FBG) as its back mirror is demonstrated for the first time. The reflection interferometer is made in SMF-28e single-mode fibre, and the faces of its front mirror, which includes a thin metallic film, differ in reflectance. The reflection bandwidth of a test sample is 0.5 pm (62 MHz) at a wavelength of 1556 nm (Q-factor of 3 ´ 10 6), its maximum reflectance is 0.21, and its contrast is 10 2. The use of a narrow-band FBG instead of thin-film broadband mirrors allows spectral selection to be significantly improved owing to an increase in the length of the interferometer base.

AB - Narrow-band filtering in reflected light using a reflection interferometer with a fibre Bragg grating (FBG) as its back mirror is demonstrated for the first time. The reflection interferometer is made in SMF-28e single-mode fibre, and the faces of its front mirror, which includes a thin metallic film, differ in reflectance. The reflection bandwidth of a test sample is 0.5 pm (62 MHz) at a wavelength of 1556 nm (Q-factor of 3 ´ 10 6), its maximum reflectance is 0.21, and its contrast is 10 2. The use of a narrow-band FBG instead of thin-film broadband mirrors allows spectral selection to be significantly improved owing to an increase in the length of the interferometer base.

KW - Dielectric interference coating

KW - Fibre Bragg grating

KW - Fibre optics

KW - Multiple-beam interference

KW - Reflection interferometer

KW - Thin metallic film

KW - fibre optics

KW - LASER

KW - LIGHT

KW - thin metallic film

KW - multiple-beam interference

KW - reflection interferometer

KW - dielectric interference coating

KW - fibre Bragg grating

UR - http://www.scopus.com/inward/record.url?scp=85052869664&partnerID=8YFLogxK

U2 - 10.1070/QEL16695

DO - 10.1070/QEL16695

M3 - Article

AN - SCOPUS:85052869664

VL - 48

SP - 728

EP - 732

JO - Quantum Electronics

JF - Quantum Electronics

SN - 1063-7818

IS - 8

ER -

ID: 16483079