Thermal Lattice Field during Ultra-Short Laser Pulse Irradiation of Metal Targets: A Fokker–Planck Analytical Model

Thermal Lattice Field during Ultra-Short Laser Pulse Irradiation of Metal Targets: A Fokker–Planck Analytical Model

The ultrafast fs laser pulse heating of thin metal films is studied for the first time using the two-temperature model on the basis of the Fokker–Planck formalism. The incident laser radiation is multi-modal, while the electron temperature is described during the first 2 fs. The predictions are inte...

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Veröffentlicht in:Metals (Basel ) 2023-10, Vol.13 (10), p.1775
Hauptverfasser: Anghel, Sinziana-Andreea, Oane, Mihai, Mihăilescu, Cristian N., Sava, Bogdan A., Elişa, Mihail, Mihăilescu, Natalia, Ticoş, Dorina, Trefilov, Alexandra M. I., Ristoscu, Carmen, Filip, Ana V., Mihăilescu, Ion N.
Format: Artikel
Sprache:eng
Schlagworte:
analytical simulations
Dielectric films
Electron energy
Electrons
Energy
Equilibrium
Fokker–Planck analytical approach
fs laser pulses
Heat
Laser beam heating
laser heating of metals
Laser processing
Lasers
Mathematical models
Metal films
Metallic films
Metals
Optoelectronics
Phase transitions
Pulse heating
Radiation
Temperature
Thin films
two-temperature model
β parameter
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Zusammenfassung:The ultrafast fs laser pulse heating of thin metal films is studied for the first time using the two-temperature model on the basis of the Fokker–Planck formalism. The incident laser radiation is multi-modal, while the electron temperature is described during the first 2 fs. The predictions are intended for use by experimentalists in optoelectronics, photonics, laser processing, electronics, and bio- and nanomedicine. The crucial role of the nano-sized spatial dimensions of the metal sample is highlighted. A significant result of this study is the interdependence between the target’s size, the phonon/lattice characteristics, and the coefficient β (the quotient of non-diffusive phenomena), which varies between zero (pure diffusive case) and one (pure non-diffusive case).
ISSN:2075-4701
2075-4701
DOI:10.3390/met13101775