Dispersion management in organic liquid-cladding photonic crystal fiber based on GeSe2–As2Se3–PbSe chalcogenide

Author affiliations

Authors

DOI:

https://doi.org/10.15625/0868-3166/22079

Keywords:

Photonic crystal fiber, chromatic dispersion, chalcogenide; liquids

Abstract

We present a numerical study of the influence of the liquids on fiber properties. The PCF was proposed based on the GeSe2–As2Se3–PbSe chalcogenide, infiltrated with six organic liquids in air holes in the cladding. The guiding properties in terms of dispersion characteristics, mode area, nonlinear coefficient, and confinement loss of the fundamental mode were numerically investigated. The result is that it is possible to shift the wavelength of the zero dispersion by about 20 nm to longer wavelengths and to reduce the slope of the dispersion curve of the fiber by the liquid filling. The results obtained also show that the PCF has a larger mode area (lower nonlinear coefficient) when infiltrated with liquids with a higher refractive index. At the same time, the presence of liquid in the cladding is responsible for the increase in confinement loss. In particular, the fiber has a lower confinement loss when infiltrated with liquids with a higher refractive index.

Downloads

Metrics

PDF views
6

References

1. J. C. Knight, T. A. Birks, P. S. J. Russell, and D. M. Atkin, All-silica single-mode optical fiber with photonic crystal cladding, Opt. Lett. 21 (1996) 1547-1549.

2. M. A. Habib and M. S. Anower, Low loss highly birefringent porous core fiber for single mode terahertz wave guidance, Current Optics and Photonics 2 (2018) 215–20.

3. E. Wang, Q. Han, X. Zhou, H. Yuan and J. Li, A Bend-resistant Photonic Crystal Fiber with Large Effective Mode Area, Optical Fiber Technology 71 (2022) 102902.

4. R. Saha, M. M. Hossain, M. E. Rahaman, and H. S. Mondal, Design and analysis of high birefringence and nonlinearity with small confinement loss photonic crystal fiber, Front. Optoelectron. 12 (2019) 165–173.

5. Z. Shen, K. Li, C. Jia and H. Jia, Mid-infrared dual-cladding photonic crystal fiber with high birefringence and high nonlinearity, Optical Review 27 (2020) 296–303.

6. T. Sylvestre, E. Genier, A. N. Ghosh, P. Bowen, G. Genty, J. Troles, A. Mussot, A. C. Peacock, M. Klimczak, A. M. Heidt, J. C. Travers, O. Bang, J. M. Dudley, Recent advances in supercontinuum generation in specialty optical fibers [invited], J. Opt. Soc. Am. B 38 (2021) F90–F103.

7. W. J. Wadsworth, A. O. Blanch, J. C. Knight, T. A. Birks, T. P. M. Man and P. St. J. Russell, Supercontinuum generation in photonic crystal fibers and optical fiber tapers: a novel light source, Journal of the Optical Society of America B 19 (2002) 2148.

8. J.M. Dudley, G. Genty, S. Coen, Supercontinuum generation in photonic crystal fiber, Rev. Mod. Phys. 78 (2006)1135–1184.

9. G.P. Agrawal, Nonlinear Fiber Optics, Academic Press, Elsevier, 2013.

10. S. Roy, D. Ghosh, S.K. Bhadra, G.P. Agrawal, Role of dispersion profile in controlling emission of dispersive waves by solitons in supercontinuum generation, Opt. Commun. 283 (15) (2010) 3081–3088.

11. I.A. Sukhoivanov, S. O. Iakushev, O.V.Shulika, J. A. Andrade Lucio, A. Diez, M. Andres, Supercontinuum generation at 800 nm in all-normal dispersion photonic crystal fiber, Opt Express 22 (2014) 30234–50.

12. C. Huang, M. Liao, W. Bi, X. Li, L. Hu, L. Zhang, et al, Ultraflat, broadband, and highly coherent supercontinuum generation in all-solid microstructured optical fibers with all-normal dispersion, Photonics Res 6 (2018).

13. Y. Huang, H. Yang, S. Zhao, Y. Mao, S. Chen, Design of photonic crystal fibers with flat dispersion and three zero dispersion wavelengths for coherent supercontinuum generation in both normal and anomalous regions, Results Phys 23 (2021) 104033.

14. H. L. Van, V. T. Hoang, T. L. Canh, Q. H. Dinh, H. T. Nguyen, N. V. T. Minh, M. Klimczak, R. Buczynski, and R. Kasztelanic, Silica-based photonic crystal fiber infiltrated with1,2-dibromoethane for supercontinuum generation, Appl.Opt 60 (2021) 7268–78.

15. T. S. Saini, R. K. Sinha, Mid-infrared supercontinuum generation in soft-glass specialty optical fibers: A review, Progress in Quantum Electronics (78) (2021) 100342.

16. H. V. Le, V. L. Cao, H. T. Nguyen, A. M. Nguyen, R. Buczyński and R. Kasztelanic, Application of ethanol infiltration for ultra-flattened normal dispersion in fused silica photonic crystal fibers, Laser Phys. 28 (2018) 115106.

17. J. Pniewski, T. Stefaniuk, H.L. Van, V.C.Long, L.C.Van, R. Kasztelanic, G. Stepniewski, A. Ramaniuk, M. Trippenbach, R. Buczynski, Dispersion engineering in nonlinear soft glass photonic crystal fibers infiltrated with liquids, Appl. Opt. 55, (2016) 5033–5040.

18. Q. Lin, J. Zhang, P. M. Fauchet, and G. P. Agrawal, Ultrabroadband parametric generation and wavelength conversion in silicon waveguides, Opt. Express 14 (2006) 4786–4799.

19. Z. Jafari, L. Zhang, A.M. Agarwal, L.C. Kimerling, J. Michel, A. Zarifkar, Parameter Space Exploration in Dispersion Engineering of Multilayer Silicon Waveguides from Near-Infrared to Mid-Infrared, J. Light wave Technol. 34 (16) (2016) 3696–3702.

20. H.V. Le, Coherence evolution of multi-pulse pumped super-continuum in multicomponent GeSe2-As2Se3-PbSe chalcogenide photonic crystal fiber with four zero-dispersion wavelengths, Journal of the Optical Society of America B 41 (2024) 2780-2790.

21. H. L. Van, V. T. Hoang, H. T. Nguyen, V. C. Long, R. Buczynski, R. Kasztelanic, Supercontinuum generation in photonic crystal fibers infiltrated with tetrachloroethylene, Opt. Quantum Electron. 53 (187) (2021) 02820–02823.

22. Q. H. Ding, J. Pniewski, H.L.Van, A. Ramaniuk, V.C. Long, K. Borzycki, K.D. Xuan, M. Klimczak, R. Buczynski, Optimization of optical properties of photonic crystal fibers infiltrated with carbon tetrachloride for supercontinuum generation with subnanojoule femtosecond pulses, Appl. Opt. 57(14) (2018) 3738–3746.

23. C.V. Lanh, V. T. Hoang, V. C. Long, K. Borzycki, K. D. Xuan, V. T. Quoc et al., Optimization of optical properties of photonic crystal fibers infiltrated with chloroform for supercontinuum generation, Laser Phys. 29 (2019) 075107.

24. L. C. Van, A. Anuszkiewicz, A. Ramaniuk, R. Kasztelanic, K. X. Dinh, M Trippenbach et al., Supercontinuum generation in photonic crystal fibers with core filled with toluene, J. Opt. 19 (2017) 125604.

Downloads

Published

01-04-2025

How to Cite

[1]
V. H. Le, “Dispersion management in organic liquid-cladding photonic crystal fiber based on GeSe2–As2Se3–PbSe chalcogenide ”, Comm. Phys., vol. 35, no. 1, p. 87, Apr. 2025.

Issue

Vol. 35 No. 1 (2025)

Section

Papers

License

Authors who publish with CIP agree with the following terms:
  1. The manuscript is not under consideration for publication elsewhere. When a manuscript is accepted for publication, the author agrees to automatic transfer of the copyright to the editorial office.
  2. The manuscript should not be published elsewhere in any language without the consent of the copyright holders. Authors have the right to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal’s published version of their work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
  3. Authors are encouraged to post their work online (e.g., in institutional repositories or on their websites) prior to or during the submission process, as it can lead to productive exchanges or/and greater number of citation to the to-be-published work (See The Effect of Open Access).
Crossref
Scopus
Google Scholar
Europe PMC
Received 15-12-2024
Accepted 05-02-2025
Published 01-04-2025

Most read articles by the same author(s)