Features of the kinetics of polymers electron-beam dispersion under laser assisted conditions

M. A. Yarmolenko; A. V. Rogachev; A. S. Rudenkov; A. M. Mikhalko

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Features of the kinetics of polymers electron-beam dispersion under laser assisted conditions

M. A. Yarmolenko ; A. V. Rogachev ; A. S. Rudenkov ; A. M. Mikhalko

Problemy fiziki, matematiki i tehniki, no. 3 (2022), pp. 61-66.

Voir la notice de l'article provenant de la source Math-Net.Ru

Résumé

Analytical description of the process of charging the polymer target surface by electron beam influence under laser assisted conditions is presented. The results were used to interpret the kinetic dependences of the electron beam dispersion of PMMA, PET, PTFE under laser assist influence $\lambda = 532$ nm and $\lambda = 266$ nm. The effect of the assist radiation wavelength on the kinetic parameters of dispersion was determined. The conclusion is made about the dominant effect of the photoinitiated electron emission caused by laser radiation influence during the electron beam dispersion of PMMA. The main effect of laser radiation during the electron beam dispersing of PTFE is an additional photochemical effect. The effect of the assist radiation wavelength on the PET dispersion kinetics is explained by the different nature of the effect; the main influence of photoelectron emission under the influence of radiation with $\lambda = 266$ nm and photochemical changes under the action of radiation with $\lambda = 532$ nm.

Keywords: polymers, electron beam dispersion, surface charging, photostimulated electron emission.
Mots-clés : laser assistance

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     title = {Features of the kinetics of polymers electron-beam dispersion under laser assisted conditions},
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M. A. Yarmolenko; A. V. Rogachev; A. S. Rudenkov; A. M. Mikhalko. Features of the kinetics of polymers electron-beam dispersion under laser assisted conditions. Problemy fiziki, matematiki i tehniki, no. 3 (2022), pp. 61-66. http://geodesic.mathdoc.fr/item/PFMT_2022_3_a9/

Bibliographie
Cité par

[1] H. Deng et al., “Review on the laser-induced performance of photothermal materials for ignition application”, Energetic Materials Frontiers, 2 (2021), 201–217 | DOI

[2] Y. Jing et al., “An overview of surface-enhanced Raman scattering substrates by pulsed laser deposition technique: fundamentals and applications”, Advanced Composites and Hybrid Materials, 4 (2021), 885–905 | DOI

[3] Y. Liu et al., “Low-energy electron beam deposition of coatings based on lignin and quercetin, their structure and properties”, Vacuum, 205 (2022), 111416 | DOI

[4] M.A. Yarmolenko, A.A. Rogachev, A.V. Rogachev, “Osobennosti elektronno-luchevogo dispergirovaniya bromida serebra v usloviyakh lazernogo assistirovaniya, sostav i morfologiya osazhdaemykh pokrytii”, Nanomaterialy i nanostruktury - XXI vek, 8 (2017), 32–38 | Zbl

[5] A.V. Rogachev, M.A. Yarmolenko, A.A. Rogachev, D.L. Gorbachev, “Plazmokhimicheskii sintez nanokompozitsionnykh plazmonnykh pokrytii”, Izvestiya Gomelskogo gosudarstvennogo universiteta imeni F. Skoriny, 2011, no. 6 (69), 110–117

[6] M.A. Yarmolenko i dr., Mikro- i nanokompozitsionnye polimernye pokrytiya, osazhdaemye iz aktivnoi gazovoi fazy, ed. A.V. Rogachev, Radiotekhnika, M., 2016, 424 pp.

[7] K.P. Gritsenko, A.M. Krasovsky, “Thin-Film Deposition of Polymers by Vacuum Degradation”, Chem. Rev., 103:9 (2003), 3607–3649 | DOI

[8] M.E. Borisova, Izmeneniya v polimernykh telakh pod deistviem zaryazhennykh chastits nevysokoi energii, avtoref. diss. na soiskanie uch. st. kand. fiz.-mat. nauk: 01.04.19, L., 1974, 20 pp.

[9] A.A. Rogachev, Fiziko-khimiya polimernykh pokrytii, osazhdaemykh iz aktivnoi gazovoi fazy, Nauchnyi mir, M., 2014, 287 pp.

[10] G. Messa, E. Barkhop, Elektronnye i ionnye stolknoveniya, per. s angl., ed. S. M. Osovets, Inostr. lit., M., 1958, 604 pp.

[11] B.I. Sazhin, Elektricheskie svoistva polimerov, Khimiya, L., 1986, 224 pp.

[12] S. Madorskii, Termicheskoe razlozhenie organicheskikh polimerov, Mir, M., 1967, 328 pp.

[13] A.V. Rogachev, Issledovanie protsessov formirovaniya metallicheskikh plenok na poverkhnostyakh polimerov v vakuume, avtoref. diss. na soiskanie uch. st. kand. tekh. nauk: 01.04.19, IMP AN. Latv. SSR, Riga, 1979, 20 pp.

[14] Dzh. Gillet, Fotofizika i fotokhimiya polimerov. Vvedenie v izuchenie fotoprotsessov v makromolekulakh, Mir, M., 1988, 435 pp.