Shapeable Material Technologies for 3D Self‐Assembly of Mesoscale Electronics

Karnaushenko, Daniil; Kang, Tong; Schmidt, Oliver G.

doi:10.1002/admt.201800692

Cited by 45 publications

(38 citation statements)

References 239 publications

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“…6a). The fabrication starts with a shapeable polymeric layer stack 21 (SPS) required for self-assembly of the magnetic rotor comprising a 100-nm-thick metal organic SL, 100-nm-thick hydrogel (HG), and 200-nm-thick polyimide (PI). Then the whole structure is covered with 15 nm Al 2 O 3 and followed by a capacitor stack containing another 15 nm of Al 2 O 3 sandwiched between two 40 nm Al electrodes.…”

Section: Resultsmentioning

confidence: 99%

“…It is, however, striking that self-assembly of mass-produced 3D electronic devices has failed to enter any industrial-level manufacturing schemes even nowadays. Among various self-assembly strategies, so-called “micro-Origami” which is the art of self-folding two-dimensional (2D) nanomembranes into micro-architectures 4–9 , has opened up novel ways in constructing 3D mesoscale devices of “Swiss-roll” 10–16 , polyhedral 17,18 and even more complex 19,20 shapes benefiting from state-of-the-art wafer-scale manufacturing technologies 21–23 . However, mesoscale 3D self-assembly of nanomembrane devices faces severe challenges associated with low yield, wide parameter spreading, and bad reproducibility.…”

Section: Introductionmentioning

confidence: 99%

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Magnetic origami creates high performance micro devices

2019

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Self-assembly of two-dimensional patterned nanomembranes into three-dimensional micro-architectures has been considered a powerful approach for parallel and scalable manufacturing of the next generation of micro-electronic devices. However, the formation pathway towards the final geometry into which two-dimensional nanomembranes can transform depends on many available degrees of freedom and is plagued by structural inaccuracies. Especially for high-aspect-ratio nanomembranes, the potential energy landscape gives way to a manifold of complex pathways towards misassembly. Therefore, the self-assembly yield and device quality remain low and cannot compete with state-of-the art technologies. Here we present an alternative approach for the assembly of high-aspect-ratio nanomembranes into microelectronic devices with unprecedented control by remotely programming their assembly behavior under the influence of external magnetic fields. This form of magnetic Origami creates micro energy storage devices with excellent performance and high yield unleashing the full potential of magnetic field assisted assembly for on-chip manufacturing processes.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Magnetic origami creates high performance micro devices

2019

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“…A set of novel wafer-scale technologies have led to new origami-like MEMS and NEMS architectures [34] based on mechanically active and stimuli-responsive materials which can be summarized into the class of shapeable materials technologies. [56] Planar patterns prepared from these materials via lithographic and thin-film methods can be released from the carrying substrate and then deployed to form 3D architectures in a way similar to how origami is assembled from a piece of paper. In contrast to this classical handmade craft, the structures created by shapeable materials technologies rely on monolithic, parallel self-reshaping principles generating complex mesoscale architectures on a wafer scale.…”

Section: D Microelectronicsmentioning

confidence: 99%

3D Self‐Assembled Microelectronic Devices: Concepts, Materials, Applications

et al. 2019

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www.advmat.de www.advancedsciencenews.com photolithography techniques. New amorphous semiconducting materials are involved in the development of flexible electronics based on high-performance compounds that include organic [82] and inorganic (e.g., copper oxide [83] or indium-gallium-zinc oxide (IGZO) [84] ) semiconductor possessing, for instance, the transparency [85] required in optoelectronic applications. Once fabricated on polymeric ultrathin substrates, these devices offer the flexibility, stretchability, and imperceptibility [85][86][87] for onskin (Figure 3 a,b,d) biomedical applications, such as biosensors capable of conformally wrapping a soft or irregularly shaped 3D biological sample such as a cancer cell or a pollen grain. [88] Demonstrating outstanding mechanical stability, thin-film materials, in particular semiconductors, are superior candidates for 3D applications compared to monocrystalline semiconductors. [87,89,90] Good examples are amorphous oxides and some organic molecular semiconductors [82] (Figure 3b-d) which are particularly attractive for 3D self-assembled microelectronics. By employing substrates with a thickness in the micro-and submicrometer range (Figure 3) many issues associated with mechanical stress on the surface could be mitigated, demonstrating the increased robustness and reliability of thinfilm electronics. [87,89] Electronic skin (e-skin) (Figure 3a,b,d), for Adv. Mater. 2020, 32, 1902994 Adv. Mater. 2020, 32, 1902994 Figure 3. Thin-film flexible electronic devices and applications. a) Mechanical prosthesis with stretchable electronic skin. Adapted with permission. [97] Copyright 2014, Springer Nature. b) Schematics and photograph of imperceptible organic electronics equipped with tactile active sensor matrix. Adapted with permission. [87] Copyright 2013, Springer Nature. c) Complex circuits with 8-bit microprocessors made of 3381 organic thin-film transistors. Adapted with permission. [98] Copyright 2012, IEEE. d) Ultrathin substrate combined with high-performance indium-gallium-zinc oxide (IGZO) circuitry paving the way for active medical devices on contact lenses. [85] Adapted with permission. [85] Copyright 2014, Springer Nature.

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“…Rolled‐up nanotechnology has offered an advanced platform based on strain engineering to deterministically rearrange 2D nanomembranes into 3D structures realizing complex 3D micro‐ and nanoelectronic as well as optical and microfluidic components. [ 5–9 ] Over the past decades SRM‐based electronic devices with outstanding performance such as SRM capacitors, [ 10–14 ] inductors, [ 15–19 ] transistors, [ 20–22 ] sensors, [ 23,24 ] diodes, [ 25 ] and antennas [ 26 ] have been successfully demonstrated. The SRM devices are by nature thin‐film structures that are self‐assembled into 3D microarchitectures.…”

Section: Introductionmentioning

confidence: 99%

Mechanical Characterization of Compact Rolled‐up Microtubes Using In Situ Scanning Electron Microscopy Nanoindentation and Finite Element Analysis

et al. 2021

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Self‐assembled Swiss‐roll microstructures (SRMs) are widely explored to build up microelectronic devices such as capacitors, transistors, or inductors as well as sensors and lab‐in‐a‐tube systems. These devices often need to be transferred to a special position on a microchip or printed circuit board for the final application. Such a device transfer is typically conducted by a pick‐and‐place process exerting enormous mechanical loads onto the 3D components that may cause catastrophic failure of the device. Herein, the mechanical deformation behavior of SRMs using experiments and simulations is investigated. SRMs using in situ scanning electron microscopy (SEM) combined with nanoindentation are characterized. This allows us to mimic and characterize mechanical loads as they occur in a pick‐and‐place process. The deformation response of SRMs depends on three geometrical factors, i.e., the number of windings, compactness of consecutive windings, and inner diameter of the microtube. Nonlinear finite element analysis (FEA) showing good agreement with experiments is performed. It is believed that the insights into the mechanical loading of 3D self‐assembled architectures will lead to novel techniques suitable for a new generation of pick‐and‐place machines operating at the microscale.

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Shapeable Material Technologies for 3D Self‐Assembly of Mesoscale Electronics

Cited by 45 publications

References 239 publications

Magnetic origami creates high performance micro devices

Magnetic origami creates high performance micro devices

3D Self‐Assembled Microelectronic Devices: Concepts, Materials, Applications

Mechanical Characterization of Compact Rolled‐up Microtubes Using In Situ Scanning Electron Microscopy Nanoindentation and Finite Element Analysis

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