eISSN:2278-5299

International Journal of Latest Research in Science and Technology

DOI:10.29111/ijlrst   ISRA Impact Factor:3.35,  Peer-reviewed, Open-access Journal

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NUMERICAL, TWO-DIMENSIONAL ABLATION MODEL FOR INTERFERING, HIGH POWER LASER BEAMS

Research Paper Open Access

International Journal of Latest Research in Science and Technology Vol.2 Issue 5, pp 18-25,Year 2013

NUMERICAL, TWO-DIMENSIONAL ABLATION MODEL FOR INTERFERING, HIGH POWER LASER BEAMS

Jan Marczak, Karol Jach, Robert ?wierczy?ski, Marek Strzelec

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Received : 22 October 2013; Accepted : 27 October 2013 ; Published : 31 October 2013

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Article No. 10200
Abstract

The article presents two dimensional – 2D(x,y) numerical ablation model, which describes simultaneous interaction, in close proximity, of two and three high power pulsed laser beams. Such pulsed laser beams may be generated as a result of, e.g., interference of two high power pulsed laser beams. Geometry of the sample and method of its illumination were presented. Illuminated disk was constituted by an aluminium layer with a thickness of 400 nm, lying on a quartz substrate with a thickness of 900 nm. Results of numerical calculations, presented in the article, were selected from many previously-performed numerical simulations for two and three simultaneously interacting pulsed laser beams, dependent on their intensity and their reciprocal distance, taking into account the material parameters of the selected target. Equations describing the problem of interaction between high power pulsed radiation and an aluminium target, which were presented and described in the article, were solved numerically using the free particle method.

Key Words   
2D(x,y) numerical model; pulsed laser; direct lithography; interference; laser ablation
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To cite this article

Jan Marczak, Karol Jach, Robert ?wierczy?ski, Marek Strzelec , " Numerical, Two-dimensional Ablation Model For Interfering, High Power Laser Beams ", International Journal of Latest Research in Science and Technology . Vol. 2, Issue 5, pp 18-25 , 2013


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