Spatio‐temporal dynamics in nondiffractive Bessel ultrafast laser nanoscale volume structuring

Velpula, Praveen Kumar; Bhuyan, M. K.; Courvoisier, F.; Zhang, Hao; Colombier, Jean‐Philippe; Stoian, Razvan

doi:10.1002/lpor.201500112

Cited by 58 publications

(80 citation statements)

References 69 publications

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“…This is first visible in the augmentation of the absorption level due to free carriers [ Figure 7(a)], as well as in the subsequent increase in the magnitude of the launched pressure wave [ Figure 7(b)]. A scenario discussing the role of pulse duration in defining the level and the shape of the absorption region was discussed earlier [7,23] . The pulse durations that achieved the maximal carrier density and pressure yield respectively are slightly shifted, indicating that the released pressure only partially reflects the initial energy concentration, part of the energy being spent in plastic compaction around the damage region.…”

Section: Irradiation and Control By Temporally Shaped Pulsesmentioning

confidence: 98%

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Excitation and relaxation dynamics in ultrafast laser irradiated optical glasses

Mauclair

Mermillod–Blondin

Mishchik

et al. 2016

High Pow Laser Sci Eng

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We discuss the dynamics of ultrashort pulsed laser excitation in bulk optical silica-based glasses (fused silica and borosilicate BK7) well-above the permanent modification threshold. We indicate subsequent structural and thermomechanical energy relaxation paths that translate into positive and negative refractive index changes, compression and rarefaction zones. If fast electronic decay occurs at low excitation levels in fused silica via self-trapping of excitons, for carrier densities in the vicinity of the critical value at the incident wavelength, persistent long-living absorptive states indicate the achievement of low viscosity matter states manifesting pressure relaxation, rarefaction, void opening and compaction in the neighboring domains. An intermediate ps-long excited carrier dynamics is observed for BK7 in the range corresponding to structural expansion and rarefaction. The amount of excitation and the strength of the subsequent hydrodynamic evolution is critically dependent on the pulse time envelope, indicative of potential optimization schemes.

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Section: Irradiation and Control By Temporally Shaped Pulsesmentioning

confidence: 98%

“…dielectrics follow short-and long-living absorption phases, associated to carrier dynamics in strong or weak interaction with the glass matrix [7,[13][14][15] . The material structurally responds to this dynamics on various timescales with structural states ranging from densification (type I) to rarefaction (type II) [16][17][18][19] .…”

Section: Introductionmentioning

confidence: 99%

Excitation and relaxation dynamics in ultrafast laser irradiated optical glasses

Mauclair

Mermillod–Blondin

Mishchik

et al. 2016

High Pow Laser Sci Eng

Self Cite

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“…In contrast to high-angle Bessel beams, the laser pulse gets strongly perturbed and defocused by the nonlinear Kerr effects and induced plasma [14], that is similar to the femtosecond (fs) filamentary propagation using low NA conventional focusing optics [15]. As a consequence, a relatively low free electrons concentration and weaker material damage than expected from linear propagation dynamics is observed [16,17]. When even smaller conical angles θ B <10 • are employed, these nonlinear effects completely prevent the formation of permanent modifications [17].…”

Section: Introductionmentioning

confidence: 98%

“…When even smaller conical angles θ B <10 • are employed, these nonlinear effects completely prevent the formation of permanent modifications [17]. One way to overcome this problem is to pre-chirp the laser pulse [16,18] or use space-time focusing [19,20] and rely on temporal compression dynamics to increase the laser intensity and, thus, the energy deposition inside the medium. By using such techniques, Bessel beams were successfully employed for microstructuring of glass and semiconductors [21][22][23], drilling of microchannels in glass and silicon [18,24], as well as for cutting of thick glasses [7].…”

Section: Introductionmentioning

confidence: 99%

Improved laser glass cutting by spatio-temporal control of energy deposition using bursts of femtosecond pulses

Mishchik¹,

Beuton²,

Caulier³

et al. 2017

Opt. Express

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Abstract:We demonstrate the advantage of combining non-diffractive beam shapes and femtosecond bursts for volume laser processing of transparent materials. By re-distribution of the single laser pulse energy into several sub-pulses with 25 ns time delay, the energy deposition in the material can be enhanced significantly. Our combined experimental and theoretical analysis shows that in burst-mode detrimental defocusing by the laser generated plasma is reduced, and the non-diffractive beam shape prevails. At the same time, heat accumulation during the interaction with the burst leads to temperatures high enough to induce material melting and even in-volume cracks. In an exemplary case study, we demonstrate that the formation of these cracks can be controlled to allow high-speed and high-quality glass cutting.

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“…Indeed, long cylindrical micro-channels with high aspect ratios [8,9] up to 1200 have been demonstrated with singleshot ultrafast pulsed Bessel beams. The previous study with Bessel beam of variable pulse duration [10] also suggested that ps pulses are more beneficial for high efficiency energy deposition and could avoid temporal dynamics effects [11,12] which can compromise the stationarity of the Bessel beam propagation. Bhuyan et al [13] demonstrated that rear-side ablation under water immersion is a good strategy to facilitate debris evacuation and for obtaining taper-free micro/nano channel fabrication.…”

Section: Introductionmentioning

confidence: 99%

Front-surface fabrication of moderate aspect ratio micro-channels in fused silica by single picosecond Gaussian–Bessel laser pulse

et al. 2018

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Single-shot Gaussian-Bessel laser beams of 1 ps pulse duration and of ~ 0.9 μm core size and ~ 60 μm depth of focus are used for drilling micro-channels on front side of fused silica in ambient condition. Channels ablated at different pulse energies are fully characterized by AFM and post-processing polishing procedures. We identify experimental energy conditions (typically 1.5 µJ) suitable to fabricate non-tapered channels with mean diameter of ~ 1.2 µm and length of ~ 40 μm while maintaining an utmost quality of the front opening of the channels. In addition, by further applying accurate post-polishing procedure, channels with high surface quality and moderate aspect ratio down to a few units are accessible, which would find interest in the surface micro-structuring of materials, with perspective of further scalability to meta-material specifications.

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Spatio‐temporal dynamics in nondiffractive Bessel ultrafast laser nanoscale volume structuring

Cited by 58 publications

References 69 publications

Excitation and relaxation dynamics in ultrafast laser irradiated optical glasses

Excitation and relaxation dynamics in ultrafast laser irradiated optical glasses

Improved laser glass cutting by spatio-temporal control of energy deposition using bursts of femtosecond pulses

Front-surface fabrication of moderate aspect ratio micro-channels in fused silica by single picosecond Gaussian–Bessel laser pulse

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