Diffraction on a Microbubble and the Morphology of the Silicon Surface Irradiated through Glycerol by a Pair of Femtosecond Laser Pulses

The effect of two successive laser pulses on silicon placed in glycerol has been studied experimentally and numerically with electromagnetic, hydrodynamic, and atomistic simulation programs. It has been shown that a microbubble in the liquid is formed on the surface after the first pulse; then, the...

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Bibliographic Details
Published inJETP letters Vol. 113; no. 2; pp. 75 - 81
Main Authors Inogamov, N. A., Romashevskiy, S. A., Ignatov, A. I., Zhakhovsky, V. V., Khokhlov, V. A., Eganova, E. M., Pershina, E. A., Ashitkov, S. I.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 2021
Springer Nature B.V
Subjects
Atomic
Biological and Medical Physics
Biophysics
Diameters
Diffraction patterns
Femtosecond pulses
Gaussian beams (optics)
Glycerol
Grooves
Heating
Light diffraction
Luminous intensity
Molecular
Molecular dynamics
Morphology
Optical and Plasma Physics
Optics and Laser Physics
Particle and Nuclear Physics
Physics
Physics and Astronomy
Quantum Information Technology
Ridges
Silicon
Solid State Physics
Spintronics
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Summary:The effect of two successive laser pulses on silicon placed in glycerol has been studied experimentally and numerically with electromagnetic, hydrodynamic, and atomistic simulation programs. It has been shown that a microbubble in the liquid is formed on the surface after the first pulse; then, the second pulse whose width is comparable with the diameter of the microbubble is diffracted on this microbubble. The calculated diffraction pattern and light intensity distribution on the silicon surface indicate that the maximum intensity at the diffraction peaks can be noticeably higher than the intensity on the axis of the incident Gaussian beam. An increase in the intensity concentrated in one bright narrow ring around the microbubble results in the formation of a characteristic groove surrounded by ridges on silicon. The molecular dynamics simulation has shown that intense heating at the diffraction peak is responsible for the melting and displacement of the melt from the center of heating. This leads to the formation of grooves with ridges having a profile similar to that measured in the experiment.
ISSN:0021-3640
1090-6487
DOI:10.1134/S0021364021020065