4.8 Article

Real-Time 3D Visualization of the Formation of Micrograting Structures Upon Direct Laser Interference Patterning of Ge

Journal

LASER & PHOTONICS REVIEWS
Volume -, Issue -, Pages -

Publisher

WILEY-V C H VERLAG GMBH
DOI: 10.1002/lpor.202300145

Keywords

capillary flow; excimer lasers; laser processing; light diffraction; melting; real-time reflectivity

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Direct Laser Interference Patterning (DLIP) is a versatile technique for fabricating periodic micro- to nanometric scale structures. This study combines deep-ultraviolet (UV) DLIP with real-time optical reflectivity and diffraction techniques to investigate the formation dynamics of grating structures with periods down to 740 nm. The results reveal the importance of considering Marangoni convection and thermocapillary waves in the formation process of 3D structures. This technique has the potential to unravel the formation dynamics of various periodic structures in different materials.
Direct Laser Interference Patterning (DLIP) is a versatile technique that enables the fabrication of periodic micro- to nanometric scale structures over large areas in a variety of materials. The periodically modulated excitation pattern can be exploited to trigger a range of complex processes, including heating, melting, ablation, and matter reorganization.In this work, a novel strategy is developed to combine deep-ultraviolet (UV) DLIP (lambda = 193 nm, tau = 23 ns) and real-time optical reflectivity and diffraction techniques to unravel the formation dynamics of grating structures with periods down to ? = 740 nm. Applied to crystalline Ge wafers, single-pulse topography modulation profiles with amplitudes up to 85 nm can be imprinted. Moreover, the dynamics of the melting and solidification processes, as well as the surface topography deformation, can be followed in real-time. Combined with a model, changes in topography over time with ns resolution can be obtained. The results unambiguously reveal that the formation process of the 3D structures can only be understood when taking both Marangoni convection and thermocapillary waves into account. The technique presented here has the potential to unravel the formation dynamics of a wide range of periodic structures in other materials.

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