Surface nanodeformations caused by ultrashort laser pulse

Autor:	Yu. V. Petrov, Y. Kato, Vladimir E. Fortov, Vasily Zhakhovsky, Momoko Tanaka, Nail Inogamov, Viktor Khokhlov, Sergei I. Anisimov, Mikhail B. Agranat, Takeshi Kaihori, Takashi Imazono, Masahiko Ishino, Yuji Fukuda, Yu. Emirov, Yoshihiro Ochi, Brian Demaske, S. I. Ashitkov, Masaki Kando, Satoshi Tamotsu, Masaharu Nishikino, Ivan Oleynik, Igor Yu. Skobelev, Toshiyuki Ohba, Tetsuya Kawachi, A. Ya. Faenov, T. A. Pikuz, N. Hasegawa
Rok vydání:	2015
Předmět:	Materials science Recrystallization (geology) business.industry General Engineering Laser Hardness Molecular physics law.invention Shock (mechanics) Optics law Ultimate tensile strength General Materials Science Surface layer Crystallization Dislocation business
Zdroj:	Engineering Failure Analysis. 47:328-337
ISSN:	1350-6307
DOI:	10.1016/j.engfailanal.2013.12.009
Popis:	Ultrashort laser pulse is a unique nanometallurgical tool which operates at extreme conditions: ultimate strength of material, the smallest spatiotemporal scales, and nonequlibrium crystallization. Approaches to ultimate strength and to highly nonequlibrium crystallization are tightly coupled with the smallness of spatiotemporal scales. Usage of the tool opens new opportunities to create materials with enhanced surface hardness, anticorrosion properties, and diverted optical constants. To use these advantages we have first of all to develop clear and reliable physical model. The paper presents new results concerning interactions of optical or X-ray lasers with metals. It is shown that ultrashort laser pulse melts surface layer, sends shock into bulk, and foams molten metal. Dense dislocation bilayer is created thanks to fast recrystallization (the first sublayer) and plastic transformations behind strong shock (the second sublayer). Plastic shock generated at moderate laser intensities attenuates sharply during its propagation into metal. During this attenuation, a plastic shock regenerates into a powerful elastic shock. This process defines boundary between the second dislocation sublayer and undamaged solid. Mechanical breaking of foam after its strong stretching and fly away of a part of melt together with fast freezing are responsible for appearance of chaotic frozen nanostructures at an irradiated surface.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::0ee9875211cd50bf185f16dfdfc3de92 https://doi.org/10.1016/j.engfailanal.2013.12.009 Zobrazit plný text záznamu Full Text from ScienceDirect