Title :
Thermal energy coupling to Al in ablation with ms-, ns-, and fs-laser pulses
Author :
Vorobyev, A.Y. ; Kuzmichev, V.M. ; Guo, Chunlei ; Kokody, N.G. ; Kohns, P.
Author_Institution :
Inst. of Opt., Rochester Univ., NY, USA
Abstract :
Residual energy coefficient defined as the ratio of thermal energy retained in aluminum sample following laser ablation to the energy of incident laser radiation as a function of laser fluence was studied. Experiments were performed in various gas media with the use of ms-and ns-ruby, ns-Nd:glass, and fs-Ti:sapphire lasers. For ns- and fs-laser pulses an abrupt significant rise of residual energy coefficient of aluminum occurs above the ablation threshold in a gas medium and does not occur in vacuum. For ms-laser pulses the residual energy coefficient increases slightly both in air and vacuum in the range of laser fluences above the ablation threshold.
Keywords :
aluminium; high-speed optical techniques; laser ablation; neodymium; ruby; solid lasers; thermo-optical effects; titanium; Al2O3:Ti; SiO2:Nd; ablation threshold; aluminum sample; fs-Ti:sapphire laser; fs-laser pulses; gas media; incident laser radiation; laser ablation; laser fluence; ms-laser pulses; ms-ruby laser; ns-Nd:glass laser; ns-laser pulses; ns-ruby laser; residual energy coefficient; thermal energy coupling; Aluminum; Artificial intelligence; Elementary particle vacuum; Energy measurement; Gas lasers; Laser ablation; Optical coupling; Optical pulse generation; Optical pulses; Temperature measurement;
Conference_Titel :
Laser and Fiber-Optical Networks Modeling, 2004. Proceedings of LFNM 2004. 6th International Conference on
Print_ISBN :
0-7803-8429-6
DOI :
10.1109/LFNM.2004.1382490
