Formation of periodic ripples through excitation of ∼1μm spot using femtosecond-laser Bessel beam on c-Si

•Sub-wavelength periodic ripples are formed by a femtosecond laser Bessel beam on c-Si in vacuum.•The periodic pattern extends along the laser-polarization direction to reach a very low fluence zone, suggesting surface EM waves propagating from the peak fluence point.•Circular polarization ablates a...

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Bibliographic Details
Published in:Applied surface science 2015-10, Vol.353, p.400-404
Main Authors: Sugawara, Ryo, Sekiguchi, Shota, Yagi, Takashi
Format: Article
Language:English
Subjects:
Ablation
Axicon
Craters
Femtosecond
Fluence
Laser beams
Lasers
Machining
Micromachining
Nanotechnology
Periodic ripple
Plasmon
Polariton
Ripples
Shot
Silicon
Spots
Surface
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Summary:•Sub-wavelength periodic ripples are formed by a femtosecond laser Bessel beam on c-Si in vacuum.•The periodic pattern extends along the laser-polarization direction to reach a very low fluence zone, suggesting surface EM waves propagating from the peak fluence point.•Circular polarization ablates a hole of ∼600-nm diameter with a perfectly round opening. We investigated the effect of periodic trenches (ripples) formed through sub-micrometer machining by focusing linearly polarized femtosecond laser pulses with conical axicons to a ∼1μm spot on c-Si in vacuum. The machined patterns were compared with the fluence distribution in the Bessel zone observed with a CCD camera. A fluence well below the ablation threshold successively forms a modification pattern, periodic ripples, and a crater with increasing number of laser shots. The rippled zone covers an area larger than the expected domain of laser modification and extends along the polarization direction of the laser beam. In contrast, a circularly polarized laser beam forms a round hole with a clear edge and does not leave a ripple-like corrugation. In comparison with a laser beam with circular polarization, a laser beam with linear polarization having the same fluence forms a crater with less laser shots because of pre-formed ripples but at the expense of degrading the machining quality. These results suggest that the formation of ripples results from surface plasmon waves generated at the peak fluence point. The periodic ripples can potentially be applied in the fabrication of gratings and photonic crystals.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2015.06.108