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1. Towards an understanding of particle-scale flaws and microstructure evolution in cold-spray via accumulation of single particle impacts

Author

Reiser, Alain and Schuh, Christopher Allan

Subjects
Condensed Matter - Materials Science
Abstract

Cold spray coatings are the sum of countless individual bonding events between single particles impacting on top of one another at high velocities. Thus, the collective behavior of microparticles must be considered to elucidate the origins of coating flaws at the scale of the particles and larger, or the dynamic evolution of the overall coating microstructure. Laser-induced particle impact testing (LIPIT) has been extensively used to study single-particle impacts, and in this work is adapted to study the accumulation of numerous particles with knowledge of each individual particle's impact parameters (particle size, velocity). The method reproducibly deposits stacks of gold particles (>20 particles) with different characteristic spectra of impact velocity. The observation of impact-induced erosion lets us define a critical velocity for material-build-up that is higher than that for single-particle bonding. The quantitative single-particle data are analyzed in a correlative manner to the structure and flaws in the resulting stacks, providing some first statistical connections between, e.g., strain and recrystallization, or aberrant particle characteristics and defects. The results highlight opportunities for the study of many-particle phenomena in microparticle impact -- from interaction of particles in cold spray to multi-step erosion processes -- with a quantitative view of the behavior of single particles.

Published
2024

2. Direct in- and out-of-plane writing of metals on insulators by electron-beam-enabled, confined electrodeposition with submicrometer feature size

Author

Nydegger, Mirco, Wang, Zhu-Jun, Willinger, Marc, Spolenak, Ralph, and Reiser, Alain

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

Additive microfabrication processes based on localized electroplating enable the one-step deposition of micro-scale metal structures with outstanding performance, e.g. high electrical conductivity and mechanical strength. They are therefore evaluated as an exciting and enabling addition to the existing repertoire of microfabrication technologies. Yet, electrochemical processes are generally restricted to conductive or semiconductive substrates, precluding their application in the manufacturing of functional electric devices where direct deposition onto insulators is often required. Here, we demonstrate the direct, localized electrodeposition of copper on a variety of insulating substrates, namely Al2O3, glass and flexible polyethylene, enabled by electron-beam-induced reduction in a highly confined liquid electrolyte reservoir. The nanometer-size of the electrolyte reservoir, fed by electrohydrodynamic ejection, enables a minimal feature size on the order of 200 nm. The fact that the transient reservoir is established and stabilized by electrohydrodynamic ejection rather than specialized liquid cells could offer greater flexibility towards deposition on arbitrary substrate geometries and materials. Installed in a low-vacuum scanning electron microscope, the setup further allows for operando, nanoscale observation and analysis of the manufacturing process.

Published
2023
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4. Metals by micro-scale additive manufacturing: comparison of microstructure and mechanical properties

Author

Reiser, Alain, Koch, Lukas, Dunn, Kathleen A., Matsuura, Toshiki, Iwata, Futoshi, Fogel, Ofer, Kotler, Zvi, Zhou, Nanjia, Charipar, Kristin, Piqué, Alberto, Rohner, Patrik, Poulikakos, Dimos, Lee, Sanghyeon, Seol, Seung K., Utke, Ivo, van Nisselroy, Cathelijn, Zambelli, Tomaso, Wheeler, Jeffrey M., and Spolenak, Ralph

Subjects
Condensed Matter - Materials Science
Abstract

Many emerging applications in microscale engineering rely on the fabrication of three-dimensional architectures in inorganic materials. Small-scale additive manufacturing (AM) aspires to provide flexible and facile access to these geometries. Yet, the synthesis of device-grade inorganic materials is still a key challenge towards the implementation of AM in microfabrication. Here, we present a comprehensive overview of the microstructural and mechanical properties of metals fabricated by most state-of-the-art AM methods that offer a spatial resolution $\leq$10$\mu$m. Standardized sets of samples were studied by cross-sectional electron microscopy, nanoindentation and microcompression. We show that current microscale AM techniques synthesize metals with a wide range of microstructures and elastic and plastic properties, including materials of dense and crystalline microstructure with excellent mechanical properties that compare well to those of thin-film nanocrystalline materials. The large variation in materials performance can be related to the individual microstructure, which in turn is coupled to the various physico-chemical principles exploited by the different printing methods. The study provides practical guidelines for users of small-scale additive methods and establishes a baseline for the future optimization of the properties of printed metallic objects $-$ a significant step towards the potential establishment of AM techniques in microfabrication.

Published
2019
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6. RETRACTED: Systematic theoretical research towards industrial application of high-speed microparticle impact resulting material modifications

Author

Wang, Yunlei, Reiser, Alain, Wang, Yunlei, and Reiser, Alain

Abstract

Microscale particle-target interactions and the resulting modifications of the target material play a crucial role in the domains of industrial manufacturing and application process. As know that the processing and manufacturing, failure prevention, and even the spacecraft protection against hypervelocity micrometeorites and orbital microdebris. Based on such an interesting, noteworthy, and profoundly applied research, it quickly followed up and compiled a series of relevant studies for particle-target interactions of high-speed microparticle impact. Here, it discussed the gas-based, laser-based, and electrostatic-based of the high-speed microparticle impacts. Among these, laser-induced particle impacts stand out for their high throughput and the suitability for operation in small facilities or even on standard laboratory optical benches. Various behaviors have been observed with smaller projectiles, relatively high velocities, and extreme strain rates, which involved the description of launching system, dynamic capturing of high-speed videography, triggering and characterization of material response, and resulting material modification. Subsequently, it conducted a summary and future prospect of the focused topics. As expected that the particle-target interactions will become an effective tool for the study of microprocessing, multi-field coupling, material strengthening and modification, it will bridge multidisciplinary to understand the scientific phenomena involved in the impact process, also provides a novel strategy for the development of next-generation of ballistic impact testing., RETRACTED: see https://doi.org/10.1016/j.mtcomm.2024.110188"Post-publication it was discovered that this paper was submitted to the journal by Yunlei Wang without the knowledge or permission of the co-author Alain Reiser. The unauthorized addition of the co-author was a result of actions taken solely by the corresponding author (Yunlei Wang) and is a clear violation of the journal's policies. The editor would like to clarify that Alain Reiser was not at fault in this matter, and his reputation and contributions should not be called into question. Should the authors decide to revise and resubmit the manuscript in accordance with the journal's policies and ethical guidelines, the editor would be happy to consider it for publication at a future date."QC 20240725

Published
2024
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7. Direct In‐ and Out‐of‐Plane Writing of Metals on Insulators by Electron‐Beam‐Enabled, Confined Electrodeposition with Submicrometer Feature Size.

Author

Nydegger, Mirco, Wang, Zhu‐Jun, Willinger, Marc Georg, Spolenak, Ralph, and Reiser, Alain

Subjects
POLYETHYLENE, MANUFACTURING processes, ELECTROPLATING, SCANNING electron microscopes, TRANSITION metals, SUBSTRATES (Materials science), ELECTRIC conductivity
Abstract

Additive microfabrication processes based on localized electroplating enable the one‐step deposition of micro‐scale metal structures with outstanding performance, e.g., high electrical conductivity and mechanical strength. They are therefore evaluated as an exciting and enabling addition to the existing repertoire of microfabrication technologies. Yet, electrochemical processes are generally restricted to conductive or semiconductive substrates, precluding their application in the manufacturing of functional electric devices where direct deposition onto insulators is often required. Here, the direct, localized electrodeposition of copper on a variety of insulating substrates, namely Al2O3, glass and flexible polyethylene, is demonstrated, enabled by electron‐beam‐induced reduction in a highly confined liquid electrolyte reservoir. The nanometer‐size of the electrolyte reservoir, fed by electrohydrodynamic ejection, enables a minimal feature size on the order of 200 nm. The fact that the transient reservoir is established and stabilized by electrohydrodynamic ejection rather than specialized liquid cells can offer greater flexibility toward deposition on arbitrary substrate geometries and materials. Installed in a low‐vacuum scanning electron microscope, the setup further allows for operando, nanoscale observation and analysis of the manufacturing process. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Microparticle Impact Testing at High Precision, Higher Temperatures, and with Lithographically Patterned Projectiles

Author

Reiser, Alain, Schuh, Christopher A., Reiser, Alain, and Schuh, Christopher A.

Abstract

In the first decade of high-velocity microparticle impact research, hardly any modification of the original experimental setup has been necessary. However, future avenues for the field require advancements of the experimental method to expand both the impact variables that can be quantitatively assessed and the materials and phenomena that can be studied. This work explores new design concepts for the launch pad (the assembly that launches microparticles upon laser ablation) that can address the root causes of many experimental challenges that may limit the technique in the future. Among the design changes contemplated, the substitution of a stiff glass launch layer for the standard elastomeric polymer layer offers a number of improvements. First, it facilitates a reduction of the gap between launch pad and target from hundreds to tens of micrometers and thus unlocks a reproducibility in targeting a specific impact location better than the diameter of the test particle itself (±1.75 µm for SiO2 particles 7.38 µm in diameter). Second, the inert glass surface enables experiments at higher temperatures than previously possible. Finally—as demonstrated by the launch of thin-film Au disks—a launch pad made of materials standard in microfabrication paves the way to facile microfabrication of advanced impactors., QC 20231106

Published
2023
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12. Microparticle Impact Testing at High Precision, Higher Temperatures, and with Lithographically Patterned Projectiles

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Reiser, Alain, Schuh, Christopher A, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Reiser, Alain, and Schuh, Christopher A

Abstract

In the first decade of high-velocity microparticle impact research, hardly any modification of the original experimental setup has been necessary. However, future avenues for the field require advancements of the experimental method to expand both the impact variables that can be quantitatively assessed and the materials and phenomena that can be studied. This work explores new design concepts for the launch pad (the assembly that launches microparticles upon laser ablation) that can address the root causes of many experimental challenges that may limit the technique in the future. Among the design changes contemplated, the substitution of a stiff glass launch layer for the standard elastomeric polymer layer offers a number of improvements. First, it facilitates a reduction of the gap between launch pad and target from hundreds to tens of micrometers and thus unlocks a reproducibility in targeting a specific impact location better than the diameter of the test particle itself (±1.75 µm for SiO2 particles 7.38 µm in diameter). Second, the inert glass surface enables experiments at higher temperatures than previously possible. Finally-as demonstrated by the launch of thin-film Au disks-a launch pad made of materials standard in microfabrication paves the way to facile microfabrication of advanced impactors.

Published
2023

21. Additive manufacturing of Zn with submicron resolution and its conversion into Zn/ZnO core–shell structures

Author

Nydegger, Mirco, Pruška, Adam, Galinski, Henning, Zenobi, Renato, Reiser, Alain, Spolenak, Ralph, Nydegger, Mirco, Pruška, Adam, Galinski, Henning, Zenobi, Renato, Reiser, Alain, and Spolenak, Ralph

Abstract

Electrohydrodynamic redox 3D printing (EHD-RP) is an additive manufacturing (AM) technique with submicron resolution and multi-metal capabilities, offering the possibility to switch chemistry during deposition “on-the-fly”. Despite the potential for synthesizing a large range of metals by electrochemical small-scale AM techniques, to date, only Cu and Ag have been reproducibly deposited by EHD-RP. Here, we extend the materials palette available to EHD-RP by using aqueous solvents instead of organic solvents, as used previously. We demonstrate deposition of Cu and Zn from sacrificial anodes immersed in acidic aqueous solvents. Mass spectrometry indicates that the choice of the solvent is important to the deposition of pure Zn. Additionally, we show that the deposited Zn structures, 250 nm in width, can be partially converted into semiconducting ZnO structures by oxidation at 325 °C in air., QC 20231106

Published
2022
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23. Targeted Additive Micromodulation of Grain Size in Nanocrystalline Copper Nanostructures by Electrohydrodynamic Redox 3D Printing

Author

Menétrey, Maxence, Koch, Lukas, Sologubenko, Alla, Gerstl, Stephan, Spolenak, Ralph, Reiser, Alain, Menétrey, Maxence, Koch, Lukas, Sologubenko, Alla, Gerstl, Stephan, Spolenak, Ralph, and Reiser, Alain

Abstract

The control of materials’ microstructure is both a necessity and an opportunity for micro/nanometer-scale additive manufacturing technologies. On the one hand, optimization of purity and defect density of printed metals is a prerequisite for their application in microfabrication. On the other hand, the additive approach to materials deposition with highest spatial resolution offers unique opportunities for the fabrication of materials with complex, 3D graded composition or microstructure. As a first step toward both—optimization of properties and site-specific tuning of microstructure—an overview of the wide range of microstructure accessed in pure copper (up to >99.9 at.%) by electrohydrodynamic redox 3D printing is presented, and on-the-fly modulation of grain size in copper with smallest segments ≈400 nm in length is shown. Control of microstructure and materials properties by in situ adjustment of the printing voltage is demonstrated by variation of grain size by one order of magnitude and corresponding compression strength by a factor of two. Based on transmission electron microscopy and atom probe tomography, it is suggested that the small grain size is a direct consequence of intermittent solvent drying at the growth interface at low printing voltages, while larger grains are enabled by the permanent presence of solvent at higher potentials., QC 20231106

Published
2022
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28. 3D electrohydrodynamic printing and characterisation of highly conductive gold nanowalls

Author

Rohner, Patrik, Reiser, Alain, Rabouw, Freddy T., Sologubenko, Alla S., Norris, David J., Spolenak, Ralph, Poulikakos, Dimos, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Soft Condensed Matter and Biophysics, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, and Soft Condensed Matter and Biophysics

Subjects
Nanostructure, Materials science, business.industry, Metallic nanostructures, 3D printing, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Surface micromachining, Nanolithography, Materials Science(all), Transmission electron microscopy, General Materials Science, Electrohydrodynamics, 0210 nano-technology, business, Electrical conductor
Abstract

3D printing research targets the creation of nanostructures beyond the limits of traditional micromachining. A proper characterisation of their functionalities is necessary to facilitate future implementation into applications. We fabricate, in an open atmosphere, high-aspect-ratio gold nanowalls by electrohydrodynamic rapid nanodripping, and comprehensively analyse their electronic performance by four-point probe measurements. We reveal the large-grained nanowall morphology by transmission electron microscopy and explain the measured low resistivities approaching those of bulk gold. This work is a significant advancement in contactless bottom-up 3D nanofabrication and characterisation and could also serve as a platform for fundamental studies of additively manufactured high-aspect-ratio out-of-plane metallic nanostructures., Nanoscale, 12 (39), ISSN:2040-3364, ISSN:2040-3372

Published
2020

29. 3D electrohydrodynamic printing and characterisation of highly conductive gold nanowalls

Author

Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Soft Condensed Matter and Biophysics, Rohner, Patrik, Reiser, Alain, Rabouw, Freddy T., Sologubenko, Alla S., Norris, David J., Spolenak, Ralph, Poulikakos, Dimos, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Soft Condensed Matter and Biophysics, Rohner, Patrik, Reiser, Alain, Rabouw, Freddy T., Sologubenko, Alla S., Norris, David J., Spolenak, Ralph, and Poulikakos, Dimos

Published
2020

30. Metals by Micro‐Scale Additive Manufacturing: Comparison of Microstructure and Mechanical Properties

Author

Reiser, Alain, primary, Koch, Lukas, additional, Dunn, Kathleen A., additional, Matsuura, Toshiki, additional, Iwata, Futoshi, additional, Fogel, Ofer, additional, Kotler, Zvi, additional, Zhou, Nanjia, additional, Charipar, Kristin, additional, Piqué, Alberto, additional, Rohner, Patrik, additional, Poulikakos, Dimos, additional, Lee, Sanghyeon, additional, Seol, Seung Kwon, additional, Utke, Ivo, additional, Nisselroy, Cathelijn, additional, Zambelli, Tomaso, additional, Wheeler, Jeffrey M., additional, and Spolenak, Ralph, additional

Published
2020
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31. Additive manufacturing of metals at small length scales – microstructure, properties and novel multi-metal electrochemical concepts

Author

Reiser, Alain, Spolenak, Ralph, Niederberger, Markus, and Greer, Julia R.

Subjects
Additive manufacturing, Microscale, Nanoscale, Metals, Natural sciences, Electrochemistry, Mechanical properties, 3D printing, ddc:500, Microstructure, FOS: Natural sciences
Abstract

Many emerging applications in microscale engineering demand the fabrication of threedimensional architectures in inorganic materials. Small-scale additive manufacturing (AM) aspires to provide access to these geometries with feature sizes in the micro- and submicrometer range. Yet, the synthesis of device-grade inorganic materials is still a challenge for AM, and the properties of additively manufactured materials are typically inferior to those of materials deposited via traditional, subtractive 2D fabrication routes – a major handicap for incorporating AM in advanced micro- and nanofabrication processes. Materials engineering is thus necessary to improve the quality of printed inorganic materials. This thesis revolves around the materials science of small-scale AM of metals, focusing on both, contemporary techniques and novel concepts introduced in this thesis. The work covers two major topics: first, it establishes a comprehensive overview of the microstructure and properties of metals synthesized by modern additive methods. Second, it explores new techniques that enable facile electrochemical AM of high-quality metals and unlock multi-metal printing of chemically architected geometries with spatially modulated properties at the submicron-scale. In combination, these studies present a further step towards the integration of AM into modern microfabrication routines. The first part of the thesis defines the state of the art of small-scale metal AM, providing a detailed literature review of current techniques and an experimental survey of their materials’ properties. Note that the thesis in general concentrates on the study and development of methods that enable direct additive deposition of metals. Thus, it considers indirect concepts based on the fabrication of organic templates by two-photon lithography in combination with subsequent metallization procedures in little detail only. Today, almost a dozen different methods are available for the direct deposition of metal 3D geometries with a resolution better than 10 μm. As these approaches build on different physico-chemical principles, their characteristics such as feature size, speed and complexity of printable geometries, as well as the synthesized metals and their microstructure, vary greatly. A discussion of the individual principles and capabilities puts the concepts in perspective to each other and projects their potentials. The thesis then presents an experimental study on the "quality" of metals deposited by these methods. In collaboration with most of the groups active in the field of small-scale metal AM, the thesis explores the microstructure and resulting mechanical properties of today’s materials. On one hand, we show that metals with a wide range of microstructures and elastic and plastic properties are synthesized. Especially electrochemical methods deposit dense and crystalline metals with excellent mechanical properties that compare well to those of thin-film nanocrystalline materials. On the other hand, the results reveal large variations in materials performance that can be related to the microstructure of the individual materials. Thus, the study provides practical guidelines for users of small-scale additive methods and establishes a baseline for the necessary optimization of printed metals. The second part of the thesis presents novel electrochemical AM methods that offer a spatial resolution 1 μm. First, two chapters introduce electrohydrodynamic redox printing (EHD-RP). This technique enables the direct, ink-free fabrication of polycrystalline multi-metal 3D structures with a resolution of 250 nm and a feature size of 100 nm. The electrochemical concept enables outstanding as-printed materials properties (for example a strength of copper that competes with highest values reported for nanocrystalline copper) printed at speeds that outperform current electrochemical techniques by one order of magnitude. Although neither its speed, its resolution nor its overall materials properties are unrivaled by competing methods, EHD-RP excels in an advantageous combination of these characteristics, readily permitting applications in microfabrication. Additionally, as a most unique feature, EHD-RP enables multi-metal printing with unprecedented detail. As shown, the additive control of the chemical architecture of metals with a chemical feature size

Published
2019

32. Additive Manufacturing of Metal Structures at the Micrometer Scale

Author

Hirt, Luca, Reiser, Alain, Spolenak, Ralph, Zambelli, Tomaso, Hirt, Luca, Reiser, Alain, Spolenak, Ralph, and Zambelli, Tomaso

Abstract

Currently, the focus of additive manufacturing (AM) is shifting from simple prototyping to actual production. One driving factor of this process is the ability of AM to build geometries that are not accessible by subtractive fabrication techniques. While these techniques often call for a geometry that is easiest to manufacture, AM enables the geometry required for best performance to be built by freeing the design process from restrictions imposed by traditional machining. At the micrometer scale, the design limitations of standard fabrication techniques are even more severe. Microscale AM thus holds great potential, as confirmed by the rapid success of commercial micro-stereolithography tools as an enabling technology for a broad range of scientific applications. For metals, however, there is still no established AM solution at small scales. To tackle the limited resolution of standard metal AM methods (a few tens of micrometers at best), various new techniques aimed at the micrometer scale and below are presently under development. Here, we review these recent efforts. Specifically, we feature the techniques of direct ink writing, electrohydrodynamic printing, laser-assisted electrophoretic deposition, laser-induced forward transfer, local electroplating methods, laser-induced photoreduction and focused electron or ion beam induced deposition. Although these methods have proven to facilitate the AM of metals with feature sizes in the range of 0.1–10 µm, they are still in a prototype stage and their potential is not fully explored yet. For instance, comprehensive studies of material availability and material properties are often lacking, yet compulsory for actual applications. We address these items while critically discussing and comparing the potential of current microscale metal AM techniques., QC 20231106

Published
2017
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35. Template-Free 3D Microprinting of Metals Using a Force-Controlled Nanopipette for Layer-by-Layer Electrodeposition

Author

Hirt, Luca, Ihle, Stephan, Pan, Zhijian, Dorwling-Carter, Livie, Reiser, Alain, Wheeler, Jeffrey M., Spolenak, Ralph, Vörös, János, Zambelli, Tomaso, Hirt, Luca, Ihle, Stephan, Pan, Zhijian, Dorwling-Carter, Livie, Reiser, Alain, Wheeler, Jeffrey M., Spolenak, Ralph, Vörös, János, and Zambelli, Tomaso

Abstract

A novel 3D printing method for voxel-by-voxel metal printing is presented. Hollow atomic force microscopy (AFM) cantilevers are used to locally supply metal ions in an electrochemical cell, enabling a localized electroplating reaction. By exploiting the deflection feedback of these probes, electrochemical 3D metal printing is, for the first time, demonstrated in a layer-by-layer fashion, enabling the fabrication of arbitrary-shaped geometries., QC 20231106

Published
2016
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36. Polymer nanocomposite patterning by dip-pen nanolithography

Author

Kandemir, Ayse Cagil, Erdem, Derya, Ma, Huan, Reiser, Alain, Spolenak, Ralph, Kandemir, Ayse Cagil, Erdem, Derya, Ma, Huan, Reiser, Alain, and Spolenak, Ralph

Abstract

The ultimate aim of this study is to construct polymer nanocomposite patterns by dip-pen nanolithography (DPN). Recent investigations have revealed the effect of the amount of ink (Laplace pressure) on the mechanism of liquid ink writing. In this study it is shown that not only the amount of ink, but also physisorption and surface diffusion are relevant. After a few writing steps, physisorption and surface diffusion outweigh the influence of the amount of ink, allowing consistent patterning governed by dwell times and writing speeds. Polymer matrices can be utilized as a delivery medium to deposit functional particles. DPN patterning of polymer nanocomposites allows for local tuning of the functionality and mechanical strength of the written patterns in high resolution, with the benefit of pattern flexibility. Typically polymer matrices with volatile components are used as a delivery medium for nanoparticle deposition, with subsequent removal of loosely bound matrix material by heating or oxygen plasma. In our study, nanocomposite patterns were constructed, and the differences between polymer and nanocomposite patterning were investigated. Cross-sectional SEM and TEM analysis confirmed that nanoparticles can be deposited with the liquid-polymer ink and are evenly distributed in the polymer matrix., QC 20231106

Published
2016
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40. Stretchable heterogeneous composites with extreme mechanical gradients

Author

Libanori, Rafael, Erb, Randall M., Reiser, Alain, Le Ferrand, Hortense, Süess, Martin J., Spolenak, Ralph, Studart, André R., Libanori, Rafael, Erb, Randall M., Reiser, Alain, Le Ferrand, Hortense, Süess, Martin J., Spolenak, Ralph, and Studart, André R.

Abstract

Heterogeneous composite materials with variable local stiffness are widespread in nature, but are far less explored in engineering structural applications. The development of heterogeneous synthetic composites with locally tuned elastic properties would allow us to extend the lifetime of functional devices with mechanically incompatible interfaces, and to create new enabling materials for applications ranging from flexible electronics to regenerative medicine. Here we show that heterogeneous composites with local elastic moduli tunable over five orders of magnitude can be prepared through the site-specific reinforcement of an entangled elastomeric matrix at progressively larger length scales. Using such a hierarchical reinforcement approach, we designed and produced composites exhibiting regions with extreme soft-to-hard transitions, while still being reversibly stretchable up to 350%. The implementation of the proposed methodology in a mechanically challenging application is illustrated here with the development of locally stiff and globally stretchable substrates for flexible electronics., QC 20231106

Published
2012
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42. Microparticle Impact Testing at High Precision, Higher Temperatures, and with Lithographically Patterned Projectiles.

Author

Reiser A and Schuh CA

Subjects
Reproducibility of Results, Temperature, Hot Temperature, Silicon Dioxide, Laser Therapy
Abstract

In the first decade of high-velocity microparticle impact research, hardly any modification of the original experimental setup has been necessary. However, future avenues for the field require advancements of the experimental method to expand both the impact variables that can be quantitatively assessed and the materials and phenomena that can be studied. This work explores new design concepts for the launch pad (the assembly that launches microparticles upon laser ablation) that can address the root causes of many experimental challenges that may limit the technique in the future. Among the design changes contemplated, the substitution of a stiff glass launch layer for the standard elastomeric polymer layer offers a number of improvements. First, it facilitates a reduction of the gap between launch pad and target from hundreds to tens of micrometers and thus unlocks a reproducibility in targeting a specific impact location better than the diameter of the test particle itself (±1.75 µm for SiO 2 particles 7.38 µm in diameter). Second, the inert glass surface enables experiments at higher temperatures than previously possible. Finally-as demonstrated by the launch of thin-film Au disks-a launch pad made of materials standard in microfabrication paves the way to facile microfabrication of advanced impactors., (© 2022 The Authors. Small Methods published by Wiley-VCH GmbH.)

Published
2023
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43. Additive manufacturing of Zn with submicron resolution and its conversion into Zn/ZnO core-shell structures.

Author

Nydegger M, Pruška A, Galinski H, Zenobi R, Reiser A, and Spolenak R

Abstract

Electrohydrodynamic redox 3D printing (EHD-RP) is an additive manufacturing (AM) technique with submicron resolution and multi-metal capabilities, offering the possibility to switch chemistry during deposition "on-the-fly". Despite the potential for synthesizing a large range of metals by electrochemical small-scale AM techniques, to date, only Cu and Ag have been reproducibly deposited by EHD-RP. Here, we extend the materials palette available to EHD-RP by using aqueous solvents instead of organic solvents, as used previously. We demonstrate deposition of Cu and Zn from sacrificial anodes immersed in acidic aqueous solvents. Mass spectrometry indicates that the choice of the solvent is important to the deposition of pure Zn. Additionally, we show that the deposited Zn structures, 250 nm in width, can be partially converted into semiconducting ZnO structures by oxidation at 325 °C in air.

Published
2022
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44. 3D electrohydrodynamic printing and characterisation of highly conductive gold nanowalls.

Author

Rohner P, Reiser A, Rabouw FT, Sologubenko AS, Norris DJ, Spolenak R, and Poulikakos D

Abstract

3D printing research targets the creation of nanostructures beyond the limits of traditional micromachining. A proper characterisation of their functionalities is necessary to facilitate future implementation into applications. We fabricate, in an open atmosphere, high-aspect-ratio gold nanowalls by electrohydrodynamic rapid nanodripping, and comprehensively analyse their electronic performance by four-point probe measurements. We reveal the large-grained nanowall morphology by transmission electron microscopy and explain the measured low resistivities approaching those of bulk gold. This work is a significant advancement in contactless bottom-up 3D nanofabrication and characterisation and could also serve as a platform for fundamental studies of additively manufactured high-aspect-ratio out-of-plane metallic nanostructures.

Published
2020
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