Ultrafast laser processing of materials: from science to industry

Malinauskas, Mangirdas; Žukauskas, Andrius; Hasegawa, S.; Hayasaki, Yoshio; Mizeikis, Vygantas; Buividas, Ričardas; Juodkazis, Saulius

doi:10.1038/lsa.2016.133

Cited by 986 publications

(506 citation statements)

References 174 publications

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“…A variety of laser-made structures and their applications have been summarized in reviews covering the topic [24,25]. By using critical point drying (CPD), which allows the elimination of capillary forces in the wet development of laser exposed polymers, it is now possible to reliably fabricate 3D structures with 100 nm structural units in 3D, as demonstrated for photonic crystals [26]. Another recent example, in which focused ultra-short laser pulses are used is controllable formation of defects inside the volume of crystals to engineer single photon emitters [27] or to tailor the photo-conductivity of dielectrics for the THz band [28,29].…”

Section: Towards 3d Nano-fabricationmentioning

confidence: 99%

Tipping solutions: emerging 3D nano-fabrication/ -imaging technologies

et al. 2017

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The evolution of optical microscopy from an imaging technique into a tool for materials modification and fabrication is now being repeated with other characterization techniques, including scanning electron microscopy (SEM), focused ion beam (FIB) milling/imaging, and atomic force microscopy (AFM). Fabrication and in situ imaging of materials undergoing a three-dimensional (3D) nano-structuring within a 1−100 nm resolution window is required for future manufacturing of devices. This level of precision is critically in enabling the cross-over between different device platforms (e.g. from electronics to micro-/ nano-fluidics and/or photonics) within future devices that will be interfacing with biological and molecular systems in a 3D fashion. Prospective trends in electron, ion, and nano-tip based fabrication techniques are presented.

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Section: Towards 3d Nano-fabricationmentioning

confidence: 99%

Tipping solutions: emerging 3D nano-fabrication/ -imaging technologies

et al. 2017

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“…All these photomodifi cation mechanisms occur simultaneously and affect polymerization, which takes approximately a millisecond for common photoresists [ 38 ] at a >90% voxel overlap at typical writing velocity of 100 µm s -1 for widespread laser 3D nanolithography. [ 39 ] In this paper, a systematic analysis via modeling and experiments is presented in order to reveal polarization effects, their infl uence on the feature size (resolution), and the coupling between thermal gradient and polarization in DLW.To study and demonstrate the polarization effects, 3D suspended resolution bridges at various angles, α , between the linear polarization and scanning direction were fabricated on a glass substrate ( Figure 1 inset in (a); see details in the Experimental Section). The line-width difference was 10%-20% (varying exposure) under typical polymerization conditions for the linearly polarized pulses.…”

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confidence: 99%

Nanoscale Precision of 3D Polymerization via Polarization Control

Rekštytė

Jonavičius

Gailevičius

et al. 2016

Advanced Optical Materials

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COMMUNICATIONand as self-organized nanopatterns induced on a surface, [ 30 ] are among other polarization-related phenomena demonstrated recently.The infl uence of beam polarization orientation on laser processing has been thoroughly studied in the cases of conductive and dielectric solid targets. [ 31,32 ] There are known effects of polarization on the scalar parameters of laser-matter interaction, such as absorption coeffi cient and ionization rate. [33][34][35][36] It is also known that heat conduction fl ux (vector) in plasma might be dependent on the direction of the imposed fi eld. [ 37 ] In what follows, these effects are considered in succession: (i) accumulation from multiple pulses, (ii) effects of polarization under high-numerical aperture (NA) focusing, and (iii) the infl uence of the external high-frequency electric fi eld on electronic heat conduction. The latter contribution has not yet been considered in laser fabrication under tight focusing. All these photomodifi cation mechanisms occur simultaneously and affect polymerization, which takes approximately a millisecond for common photoresists [ 38 ] at a >90% voxel overlap at typical writing velocity of 100 µm s -1 for widespread laser 3D nanolithography. [ 39 ] In this paper, a systematic analysis via modeling and experiments is presented in order to reveal polarization effects, their infl uence on the feature size (resolution), and the coupling between thermal gradient and polarization in DLW.To study and demonstrate the polarization effects, 3D suspended resolution bridges at various angles, α , between the linear polarization and scanning direction were fabricated on a glass substrate ( Figure 1 inset in (a); see details in the Experimental Section). The line-width difference was 10%-20% (varying exposure) under typical polymerization conditions for the linearly polarized pulses. The largest width of a 3D bridge was observed when the scan direction was perpendicular to the orientation of linear polarization, α = π / 2 ( E ⊥ v s ). The heightto-width ratio of the suspended lines was dependent on the orientation of linear polarization and changed between 3.07 and 3.44; self-focusing was not present under our experimental conditions. [ 40 ] Detailed analysis of polarization, threshold, and heat accumulation effects, which are all important, are discussed next.For the experimental conditions used, the focal spot diameter (at 1/ e 2 ) can be calculated as d f = 1.22 λ /NA = 898 nm assuming, for simplicity, a Gaussian intensity profi le. However, at such tight focusing it is necessary to use the vectorial Debye theory (specifi cs [ 41 ] can be found in Section A, Supporting Information), which predicts an ellipsoidal focal spot with two lateral cross sections: W l = 790 nm and W s = 572 nm for long and short cross sections, respectively (or 500 and 360 nm at full width at half maximum (FWHM)) for the actual experimental

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“…To date, only direct laser writing based 3DLL was shown to be capable of true 3D manufacture at the microscale. This additive manufacturing technique [35] combines a complete freedom of architecture of produced structures [36], possibility to integrate it on various substrates [37][38][39] and a large range of materials that can be processed in such fashion [40]. Here we have shown that structures produced out of zirconium containing photopolymer SZ2080 can withstand a relatively low intensity I = 86.6 W/cm 2 short wavelength exposure for prolonged time periods.…”

Section: Discussionmentioning

confidence: 82%

Optically Clear and Resilient Free-Form <em>µ</em>-Optics 3D-Printed via Ultrafast Laser Lithography

Jonušauskas

Gailevičius

Mikoliūnaitė

et al. 2016

Preprint

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Abstract:We introduce optically clear and resilient free-form micro-optical components of pure (non-photosensitized) organic-inorganic SZ2080 material made by femtosecond 3D laser lithography (3DLL). This is advantageous for rapid printing of 3D micro-/nanooptics, including their integration directly onto optical fibers. A systematic study on the fabrication peculiarities and quality of resultant structures is performed. Comparison of microlenses' resiliency to CW and femtosecond pulsed exposure is determined. Experimental results prove that pure SZ2080 is ∼3 fold more resistant to high irradiance as compared with a standard photo-sensitized material and can sustain up to 1.91 GW/cm 2 intensity. 3DLL is a promising manufacturing approach for high-intensity micro-optics for emerging fields in astro-photonics and atto-second pulse generation. Additionally, pyrolysis is employed to shrink structures up to 40% by removing organic SZ2080 constituents. This opens a promising route towards downscaling photonic lattices and creation of mechanically robust glass-ceramic structures.

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Ultrafast laser processing of materials: from science to industry

Cited by 986 publications

References 174 publications

Tipping solutions: emerging 3D nano-fabrication/ -imaging technologies

Tipping solutions: emerging 3D nano-fabrication/ -imaging technologies

Nanoscale Precision of 3D Polymerization via Polarization Control

Optically Clear and Resilient Free-Form <em>µ</em>-Optics 3D-Printed via Ultrafast Laser Lithography

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Ultrafast laser processing of materials: from science to industry

Cited by 986 publications

References 174 publications

Tipping solutions: emerging 3D nano-fabrication/ -imaging technologies

Tipping solutions: emerging 3D nano-fabrication/ -imaging technologies

Nanoscale Precision of 3D Polymerization via Polarization Control

Optically Clear and Resilient Free-Form <em>&micro;</em>-Optics 3D-Printed via Ultrafast Laser Lithography

Contact Info

Product

Resources

About

Optically Clear and Resilient Free-Form <em>µ</em>-Optics 3D-Printed via Ultrafast Laser Lithography