Journal
SURFACES AND INTERFACES
Volume 38, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.surfin.2023.102869
Keywords
LIPSS; Laser; Femtosecond; Nanostructure; Regularity; Metals
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Laser induced periodic surface structures (LIPSS) were analyzed on steel and copper surfaces in detail. The thermal conductivity differences between the two metals determine the rate of extinguishing of laser-induced temperature modulation. Femtosecond laser radiation sources with different wavelengths were used to inscribe low spatial frequency LIPSS. For steel samples, regular LIPSS were formed for both wavelengths but their regularity decreased with shorter wavelength. For copper samples, LIPSS with lower regularity were formed and even absent in one of the scanning methods at UV wavelength. Numerical analysis based on the 2D heat diffusion equation revealed that temperature modulation decreased considerably faster in copper and at higher modulation frequency.
We analyze in detail laser induced periodic surface structures (LIPSS) on steel and copper surfaces. The chosen metals exhibit extreme differences between their thermal conductivity values, which determines the rate of extinguishing of the laser-induced temperature modulation on the surface. Two wavelengths of femtosecond laser radiation sources in IR and UV spectral range were used to inscribe low spatial frequency LIPSS. Regular LIPSS were successfully formed on steel samples for both wavelengths and it was observed that their regularity decreased with shorter wavelength used to induce the structures. For copper samples, LIPSS of considerably lower regularity were formed and even absent for one of the used scanning method at UV wavelength. Experimental results were analyzed in view of the numerical solution of the 2D heat diffusion equation for induced temperature on the surface. It was found that the temperature modulation decreased considerably faster (lasting tens of picoseconds) in copper, and (additionally) the decrease of the modulation is faster at the higher modulation frequency.
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