Vol. 37, issue 01, article # 4
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Abstract:
The problem of controlling the parameters of the filamentation region of high-power femtosecond laser pulses for amplitude modulation of radiation by a metal mesh mask is theoretically considered. To this end, the initial laser beam is split into individual lower energy subbeams. This leads to a pronounced regularization of the spatial structure of the filaments, which is formed at the stage of radiation self-focusing due to diffraction interaction between subbeams in a nonlinear medium. Generally, the total length of the filamentation domain of femtosecond laser radiation in air is reduced when using modulation meshes. At the same time, the longitudinal continuity of laser plasma in such filaments can significantly increase. We show that the spatial parameters of filaments (coordinate of the start, length, and continuity) can be controlled over a wide range by changing mesh parameters (crosshair thickness and cell size), as well as the position of the mesh mask relative to the laser beam center. The results are important for predicting the propagation of high-power femtosecond laser radiation in a nonlinear medium, in particular, along atmospheric paths.
Keywords:
femtosecond laser radiation, amplitude modulation, mesh mask, self-focusing, laser filamentation, postfilament
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References:
1. Askar'yan G.A. Vozdeistvie gradienta polya intensivnogo elektromagnitnogo lucha na elektrony i atomy // ZhETF. 1962. V. 42, N 6. P. 1567–1570.
2. Braun A., Korn G., Liu X., Du D., Squier J., Mourou G. Self-channeling of high-peak-power femtosecond laser pulses in air // Opt. Lett. 1995. V. 20, N 1. P. 73–75.
3. Self-focusing: Past and Present. Fundamentals and Prospects / R.W. Boyd, S.G. Lukishova, Y.R. Shen (eds.). Berlin: Springer, 2009. 605 р.
4. Chin S.L. Femtosecond laser filamentation. New York, Springer Science + Business Media, LLC, 2010. 130 p.
5. Couairon A., Mysyrowicz A. Femtosecond filamentation in transparent media // Phys. Rep. 2007. V. 441. P. 47–189.
6. Chekalin S.V., Kandidov V.P. Ot samofokusirovki svetovykh puchkov – k filamentatsii lazernykh impul'sov // Uspekhi fiz. nauk. 2013. V. 183, N 2. P. 133–152.
7. Méchain G., Couairon A., André Y.-B., D’Amico C., Franco M., Prade B., Tzortzakis S., Mysyrowicz A., Sauerbrey R. Long-range self-channeling of infrared laser pulses in air: A new propagation regime without ionization // Appl. Phys. B. 2004. V. 79, N 3. P. 379–382.
8. Daigle J.-F., Kosareva O.G., Panov N.A., Wang T.-J., Hosseini S., Yuan S., Roy G., Chin S.L. Formation and evolution of intense, post-filamentation, ionization-free low divergence // Opt. Commun. 2011. V. 284, N 14. P. 3601–3606.
9. Apeksimov D.V., Geints Yu.E., Zemlyanov A.A., Kabanov A.M., Matvienko G.G., Oshlakov V.K. Filamentatsiya femtosekundnykh lazernykh impul'sov v vozdukhe / pod obshch. red. A.A. Zemlyanova. Tomsk: Izd-vo IOA SO RAN, 2017. 162 p.
10. Panov N.A., Kosareva O.G., Murtazin I.N. Ordered filaments of a femtosecond pulse in the volume of a transparent medium // J. Opt. Technol. 2006. V. 73, N 11. P. 778–785.
11. Apeksimov D.V., Babushkin P.A., Geints Yu.E., Zemlyanov A.A., Matvienko G.G., Oshlakov V.K., Petrov A.V., Khoroshaeva E.E. Zakonomernosti rasprostraneniya amplitudno-modulirovannogo moshchnogo femtosekundnogo lazernogo izlucheniya v vozdukhe // Optika atmosf. i okeana. 2021. V. 34, N 11. P. 837–841; Apeksimov D.V., Babushkin P.A., Geints Yu.E., Zemlyanov A.A., Matvienko G.G., Oshlakov V.K., Petrov A.V., Khoroshaeva E.E. Features of propagation of amplitude-modulated high-power femtosecond laser radiation in air // Atmos. Ocean. Opt. 2022. V. 35, N 2. P. 97–102.
12. Shipilo D.E., Panov N.A., Sunchugasheva E.S., Mokrousova D.V., Shutov A.V., Zvorykin V.D., Ustinovskii N.N., Seleznev L.V., Savel’ev A.B., Kosareva O.G., Chin S.L., Ionin A.A. Fifteen meter long uninterrupted filaments from sub-terawatt ultraviolet pulse in air // Opt. Express. 2017. V. 25, N 21. P. 25386–25391.
13. Shroeder H., Chin S.L. Visualization of the evolution of multiple filaments in methanol // Opt. Commun. 2004. V. 234. P. 399–406.
14. Kandidov V.P., Aközbek N., Scalora M., Kosareva O.G., Nyakk A.V., Luo Q., Hosseini S.A., Chin S.L. Towards a control of multiple filamentation by spatial regularization of a high-power femtosecond laser pulse // Appl. Phys. B. 2005. V. 80. P. 267–275.
15. Kosareva O.G., Nguyen T., Panov N.A., Liu W., Saliminia A., Kandidov V.P., Aközbek N., Scalora M., Vallée R., Chin S.L. Array of femtosecond plasma channels in fused silica // Opt. Commun. 2006. V. 267, N 2. P. 511–523.
16. Kul'chin Yu.N., Voznesenskii S.S., Gamayunov E.L., Golik S.S., Il'in A.A., Kamenev O.T., Nikitin A.I., Pavlov A.N., Popik A.Yu., Romashko R.V., Subbotin E.P. Fotonnye metody i tekhnologii monitoringa okeana i atmosfery // Kvant. elektron. 2020. V. 50, N 5. P. 475–488.
17. Geints Yu.E., Minina O.V., Geints I.Yu., Seleznev L.V., Pushkarev D.V., Mokrousova D.V., Rizaev G.E., Shipilo D.E., Nikolaeva I.A., Kurilova M.V., Panov N.A., Kosareva O.G., Houard A., Couairon A., Ionin A.A., Liu W. Nonlinear propagation and filamentation on 100 meter air path of femtosecond beam partitioned by wire mesh // Sensors. 2022. V. 22, N 17. Р. 1–13.
18. Mitina E., Uryupina D., Shipilo D., Nikolaeva I., Panov N., Volkov R., Kosareva O., Savel’ev A. Diffraction impact onto regularized plasma channel formation by femtosecond laser filamentation // Photonics. 2023. V. 10, N 8. P. 928-1–14.
19. Berge L., Skupin S., Lederer F., Méjean G., Yu J., Kasparian J., Salmon E., Wolf J.-P., Rodriguez M., Woste L., Bourayou R., Sauerbrey R. Multiple filamentation of terawatt laser pulses in air // Phys. Rev. Lett. 2004. V. 92. P. 225002.
20. Geints Y.E., Zemlyanov А.А. Dynamics of femtosecond synthesized coronary profile laser beam filamentation in air // J. Opt. 2021. V. 23, N 10. P. 105502.
21. Geints Yu.E., Minina O.V., Zemlyanov A.A. Self-channeling of spatially modulated femtosecond laser beams in the post-filamentation region // J. Opt. Soc. Am. B. 2022. V. 39, N 6. P. 1549–1556.
22. Geints Yu.E., Minina O.V., Mokrousova D.V., Pushkarev D.V., Rizaev G.E., Seleznev L.V. Manipulation of femtosecond laser filamentation by wire mesh amplitude mask // Opt. Commun. 2023. V. 543. P. 129595-1–10.
23. Marburger J.H. Self-focusing: Theory // Prog. Quantum Electron. 1975. V. 4, part 1. P. 35–110.
24. Zemlyanov A.A., Bulygin A.D., Geints Yu.E., Minina O.V. Dinamika svetovykh struktur pri filamentatsii femtosekundnykh lazernykh impul'sov v vozdukhe // Optika atmosf. i okeana. 2016. V. 29, N 5. P. 359–368; Zemlyanov A.A., Bulygin A.D., Geints Yu.E., Minina O.V. Dynamics of light structures during filamentation of femtosecond laser pulses in air // Atmos. Ocean. Opt. 2016. V. 29, N 5. P. 395–403.
