Effects of ion- and electron-beam treatment on surface physicochemical properties of polytetrafluoroethylene I. V. Vasenina, K. P. Savkin, O. A. Laput [et al.]
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ArticleSubject(s): политетрафторэтилен | электронно-лучевая обработка | ионная имплантация | физико-химические свойства | механические свойстваGenre/Form: статьи в журналах Online resources: Click here to access online
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Surface and coatings technology Vol. 334. P. 134-141Abstract: The investigation of the surface physicochemical and mechanical properties of polytetrafluoroethylene (PTFE) modified by ion implantation and electron-beam treatment is described. Ion implantation was carried out at doses of 1 × 1014, 1 × 1015, and 1 × 1016 ion/cm2 at an ion acceleration voltage of 20 kV; electron beam processing was performed with pulse durations of 100, 200, and 300 μs, at an acceleration voltage of 8 kV. Elemental composition, wettability and surface energy, microhardness, surface resistivity, and wear-resistance were measured after beam processing. XPS-analysis reveals that both ion and electron energy deposition lead to chemical bonding of CF3, CF and CO, which take place due to degradation processes occurring in a surface layer. It was found that the greater the irradiation dose and pulse duration, the lower the contact angle and surface resistivity are and the greater the surface energy and microhardness are. In addition, ion implantation and electron-beam treatment result in an increase of the friction coefficient, and wear track reduction, indicating wear resistance improvement.
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The investigation of the surface physicochemical and mechanical properties of polytetrafluoroethylene (PTFE) modified by ion implantation and electron-beam treatment is described. Ion implantation was carried out at doses of 1 × 1014, 1 × 1015, and 1 × 1016 ion/cm2 at an ion acceleration voltage of 20 kV; electron beam processing was performed with pulse durations of 100, 200, and 300 μs, at an acceleration voltage of 8 kV. Elemental composition, wettability and surface energy, microhardness, surface resistivity, and wear-resistance were measured after beam processing. XPS-analysis reveals that both ion and electron energy deposition lead to chemical bonding of CF3, CF and CO, which take place due to degradation processes occurring in a surface layer. It was found that the greater the irradiation dose and pulse duration, the lower the contact angle and surface resistivity are and the greater the surface energy and microhardness are. In addition, ion implantation and electron-beam treatment result in an increase of the friction coefficient, and wear track reduction, indicating wear resistance improvement.
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