Advanced laser scanning for highly-efficient ablation and ultrafast surface structuring: experiment and model

Žemaitis, Andrius; Gaidys, Mantas; Brikas, Marijus; Gečys, Paulius; Račiukaitis, Gediminas; Gedvilas, Mindaugas

doi:10.1038/s41598-018-35604-z

Cited by 106 publications

(59 citation statements)

References 80 publications

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“…In detail, the material removal in terms of one layer is presented and the discussed structures after laser machining pointing to clear growth regimes. The contour plot points to a saturation in terms of material removal rate at increasing fluence with adjacent layer depth z layer , where the slope of the iso-ablation depth lines decreases at about 10 ⋅ F th ≈ 0.65 J cm −2 in good agreement with proposed models in literature concerning efficient laser ablation [17,21]. At low feed rates and small distance between two pulses starting from moderate fluence of 0.3 J cm −2 , bumps due to heating and melting are formed, where the characteristic semispherical morphology with several 10 μm of size covers the surface [49].…”

Section: Microstructural Evolutionsupporting

confidence: 85%

“…The threshold fluence F th , defined by the power density where ablation starts for the multi-pulse regime, of stainless steel was determined for the used samples by considering the assumption for the ablation efficiency [17,21]. An optimal fluence F opt = e 2 F th follows from a logarithmic ablation law and using a Gauss intensity distribution with a beam waist w 0 the dependency of the applied peak fluence F 0 can be studied.…”

Section: Laser Ablation Strategymentioning

confidence: 99%

“…Defined ablation conditions are a prerequisite for low roughness and efficient laser ablation [17]. In principle the fluence, pulse-to-pulse distance from laser repetition rate and scan speed leads to a certain overlap linked with the focal beam waist, which are the main parameters [18].…”

Section: Introductionmentioning

confidence: 99%

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Evolution of microstructures on stainless steel induced by ultra-short pulsed laser ablation

et al. 2020

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Ultra-short pulsed laser ablation of stainless steel is accompanied by the evolution of different microstructures. Depending on the fluence, accumulated energy and number of laser passes cones from impurities, laser induced periodic surface structures, cone-like protrusion (CLP), and thermal bumps evolve at the surface. These often unwanted morphologies can be induced or inhibited by carefully choosing the strategy and laser parameters. The investigated range reveals a small processing window for defined 515 nm sub 1 ps ablation leading to low surface roughness using circular polarization. Hitherto, the origin and dependencies of CLP are still not well understood and for the first time a precursor ripple structure reported. These precursor ripples reveal supra-wavelength periodicity with about 2 μm spacing and evolve earliest after the second layer of ablation. Potentially, low spatial frequency laser-induced periodic surface structure generated with the first laser pass with pulse and hatch overlap are the root cause of CLP evolution. Moreover, the CLP growth is grain orientation and strongly polarization state dependent. Preferentially, CLP start to evolve at the {110} planes of the face-centered cubic crystals of the inspected austenitic stainless steel and linear polarized laser radiation revealing a 1:1 aspect ratio of 10 μm. A nanoindentation study at the interface near region on cross-sections reveals robust mechanical properties of this CLP structure.

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Section: Microstructural Evolutionsupporting

confidence: 85%

Section: Laser Ablation Strategymentioning

confidence: 99%

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Evolution of microstructures on stainless steel induced by ultra-short pulsed laser ablation

et al. 2020

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“…The results showed that the resolution increases with laser repetition, and it also increases as the scanning speed decreases. This could also be explained by laser fluence theory, which assumed that at low scanning speed a high number of pulses per spot were achieved because of high pulse overlap, while small laser spot size resulted in laser fluence high above the ablation threshold and large ablation depths .…”

Section: Resultsmentioning

confidence: 99%

Glass Fiber Reinforced Polycarbonate Composites for Laser Direct Structuring and Electroless Copper Plating

Wang

et al. 2020

Polymer Engineering & Sci

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Glass fiber (GF) reinforced polycarbonate (PC) composites were prepared for laser direct structuring (LDS) applications. A small amount of styrene–maleic anhydride (SMA) was introduced to enhance GF/PC interfacial interactions. The PC/SMA/GF LDS composites using metal complex as LDS additive were investigated for applicability in copper circuit development. Rough surface patterns by laser irradiation under different laser parameters were measured by microscopy and Fourier infrared spectrometry. Copper particles and plating layer by subsequent electroless copper plating procedure was observed using microscopy. Thickness of plating layer and adhesion between layer and matrix were also evaluated. The results showed that laser repetition and scanning speed led to different resolutions and ablated surfaces without structural changes of composites. Copper particles gradually deposited, grew, and interconnected during metallization procedure. Plating layer was successfully formed at an optimum LDS additive loading, and appropriate scanning speed and repetition of laser. In addition, the plating layer displayed disparate thickness and distribution, owing to different activated surfaces by irradiation. Severe ablation or unetched parallel regions resulted in leaky or discontinuous plating layer. Better plating microstructure and higher adhesion were obtained for the composite material with 1.0 wt% LDS additive loading, supporting its extensive development and practical application in LDS technology. POLYM. ENG. SCI., 60:860–871, 2020. © 2020 Society of Plastics Engineers

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“…Defined ablation conditions are a prerequisite for low roughness and efficient laser ablation [7]. In principle the fluence, laser repetition rate, and scan speed are interdependent [8] and no global optimum can be reached.…”

Section: Introductionmentioning

confidence: 99%

Evolution of Microstructures on Stainless Steel induced by Ultra-Short Laser Ablation

Ackerl¹,

Fisch²,

Auerswald³

et al. 2019

Preprint

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Ultra-short pulsed laser ablation of stainless steel is accompanied by the evolution of different microstructures. Depending on the fuence, accumulated energy and number of laser passes cones from impurities, laser induced periodic surface structures and conelike protrusion (CLP) evolve at the surface. These often unwanted morphologies can be inhibited by carefully choosing the strategy and laser parameters. Here, the identifed region shows a small processing window fordesigned 515nm sub 1 ps ablation leading to low surface roughness. CLP are still not well understood and here a pre-cursor structure is reported. Subsequently, the CLP growth is grain orientation and polarization dependent and studied in more depth. Preferentially, CLP start to evolve at the (101) grain orientations with linear polarized laser radiation. Moreover, a nanoindentation study reveals robust mechanical properties, which could be beneficial for tribology applications in the hydrodynamic regime.

show abstract

Advanced laser scanning for highly-efficient ablation and ultrafast surface structuring: experiment and model

Cited by 106 publications

References 80 publications

Evolution of microstructures on stainless steel induced by ultra-short pulsed laser ablation

Evolution of microstructures on stainless steel induced by ultra-short pulsed laser ablation

Glass Fiber Reinforced Polycarbonate Composites for Laser Direct Structuring and Electroless Copper Plating

Evolution of Microstructures on Stainless Steel induced by Ultra-Short Laser Ablation

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