Three‐Dimensional μ‐Printing: An Enabling Technology

Hohmann, Judith K.; Renner, Michael; Waller, Erik H.; Freymann, Georg von

doi:10.1002/adom.201500328

Cited by 155 publications

(111 citation statements)

References 160 publications

(281 reference statements)

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“…[1][2][3] In recent years, it has evolved as a fl exible 3D micro-/nanoprinting tool available in advanced laboratories worldwide. [4][5][6][7] DLW in polymers is based on curing a resist (resin) by nonlinear absorption at the focal volume of tightly focused high peak-power pulsedlaser radiation. Only a very small volume, which can be sub-100 nm in cross section around the focal spot, is affected during the pulsed exposure.…”

Section: Doi: 101002/adom201600155mentioning

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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Section: Doi: 101002/adom201600155mentioning

confidence: 99%

Nanoscale Precision of 3D Polymerization via Polarization Control

Rekštytė

Jonavičius

Gailevičius

et al. 2016

Advanced Optical Materials

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“…Over 200 works including several review papers [35,73,74] have been published on this hot topic since 2015. Yet, several questions have to be answered and the issues related to each of the two technologies (i.e., 3D printing and nanotechnology) have to be addressed for a further progress in the field and commercialization of the fabricated products.…”

Section: Remarks For Future Workmentioning

confidence: 99%

Printing Polymer Nanocomposites and Composites in Three Dimensions

Farahani

Dubé

2017

Adv Eng Mater

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Recent advances in materials science and three-dimensional (3D) printing hold great promises to conceive new classes of multifunctional materials and components for functional devices and products. Various functionalities (e.g., mechanical, electrical, and thermal properties, magnetism) can be offered by the nano-and micro-reinforcements to the non-functional pure printing materials for the realization of advanced materials and innovative systems. In addition, the ability to print 3D structures in a layer-by-layer manner enables manufacturing of highly-customized complex features and allows an efficient control over the properties of fabricated structures. Here, the authors present a brief overview mainly over the latest progresses in 3D printing of multifunctional polymer nanocomposites and microfiber-reinforced composites including the benefits, limitations, and potential applications. Only those 3D printing techniques that are compatible with polymer nanocomposites and composites, that is, materials that have already been used as printing materials, are introduced. The very hot topic of 3D printing of thermoplastic composites featuring continuous microfibers is also briefly introduced.

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“…[8][9][10] Im letzten Jahrzehnt hat sich hier das DLWals ein leistungsfähiges Verfahren erwiesen, um zelluläre 3D-Mikroumgebungen mit wohldefinierter Geometrie herzustellen. [4,5,[18][19][20][21][22][23][24][25][26][27][28] Hier werden wir uns hauptsächlich auf die Chemie der Photolacke fokussieren und zwei Forschungsfelder hervorheben, und zwar zusammengesetzte Zellgerüste aus zwei oder mehreren Photolacken mit unterschiedlichen biologischen Eigenschaften und Strategien zur selektiven Biofunktionalisierung in 3D. In letzter Zeit sind mehrere exzellente Übersichtsartikel über die relevante Literatur erschienen und wir verweisen auf die dort zitierten Arbeiten.…”

Section: Zellkulturanwendungenunclassified

3D‐Laser‐Mikro‐Nanodruck: Herausforderungen für die Chemie

et al. 2017

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3D‐Druck ist eine leistungsfähige Technik für die maßgeschneiderte Herstellung funktionaler Materialien. Dieser Aufsatz fasst den Stand der Technik im Hinblick auf 3D‐Laser‐Mikro‐ und ‐Nanodruck zusammen und erkundet die chemischen Herausforderungen, die derzeit die volle Etablierung dieser Technologie limitieren: von der Entwicklung fortgeschrittener Materialien für Anwendungen in der Zellbiologie und der Elektronik bis hin zu den bestehenden chemischen Grenzen des schnellen Schreibens mit Auflösungen unterhalb der Beugungsgrenze. Des Weiteren untersuchen wir Möglichkeiten zur Realisierung des direkten Laserschreibens mehrerer Materialien aus einem Photolack heraus, basierend auf wellenlängenselektiven photochemischen Prozessen (λ‐Orthogonalität). Schließlich betrachten wir chemische Prozesse, mit deren Hilfe adaptive 3D‐Strukturen geschrieben werden können, die auf externe Stimuli wie Licht, Wärme, pH‐Wert oder spezifische Moleküle reagieren, sowie fortgeschrittene Konzepte für abbaubare Stützstrukturen.

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Three‐Dimensional μ‐Printing: An Enabling Technology

Cited by 155 publications

References 160 publications

Nanoscale Precision of 3D Polymerization via Polarization Control

Nanoscale Precision of 3D Polymerization via Polarization Control

Printing Polymer Nanocomposites and Composites in Three Dimensions

3D‐Laser‐Mikro‐Nanodruck: Herausforderungen für die Chemie

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