УДК: 536.421

Controllable grain-boundary displacement during recrystallization and the microrelief of a titanium surface induced by laser radiation pulses

Makin, V.S., Pestov, Y.I., Privalov, V.E.

Publication in Journal of Optical Technology

For Russian citation (Opticheskii Zhurnal):

Макин В.С., Пестов Ю.И., Привалов В.Е. Управляемое перемещение границ зерен при рекристаллизации и микрорельеф поверхности титана , индуцированные импульсами лазерного излучения // Оптический журнал. 2013. Т. 80. № 2. С. 29–34.

Makin V.S., Pestov Yu.I., Privalov V.E. Controllable grain-boundary displacement during recrystallization and the microrelief of a titanium surface induced by laser radiation pulses [in Russian] // Opticheskii Zhurnal. 2013. V. 80. № 2. P. 29–34.

For citation (Journal of Optical Technology):

V. S. Makin, Yu. I. Pestov, and V. E. Privalov, "Controllable grain-boundary displacement during recrystallization and the microrelief of a titanium surface induced by laser radiation pulses," Journal of Optical Technology. 80(2), 91-95 (2013). https://doi.org/10.1364/JOT.80.000091

Abstract:

When multipulse laser-induced recrystallization of a titanium surface occurs under the action of polarized radiation, grain growth is detected, associated with the polarization direction of the radiation. An explanation of the observed phenomenon is given, based on the effect of electron entrainment by surface plasmon-polaritons excited at the grain boundaries.

Keywords:

polarized laser radiation, electron entrainment by surface plasmon-polaritons, recrystallization

Acknowledgements:

The authors are grateful to V. N. Petrov for making measurements of the nanorelief of the irradiated titanium surface, using an atomic-force microscope. This work was carried out with the partial financial support of Federal Special Program “Scientific and Scientific-Pedagogical Staffs of Innovation of Russia, 2009–2013,” Contract No. 16.740.11.0463 and Project No. 09-02-00932 of the Russian Foundation for Basic Research.

OCIS codes: 350.5340, 50.3390

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