Automatic Transformation of Membrane‐Type Electronic Devices into Complex 3D Structures via Extrusion Shear Printing and Thermal Relaxation of Acrylonitrile–Butadiene–Styrene Frameworks

Jang, Hun Soo; Yoo, Seonggwang; Kang, Sinhang; Park, Jongjun; Kim, Gi‐Gwan; Ko, Heung Cho

doi:10.1002/adfm.201907384

Cited by 5 publications

(2 citation statements)

References 55 publications

(87 reference statements)

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“…As complements to these schemes for direct patterning, rolling and/or folding mechanisms allow formation of certain types of 3D architectures from 2D precursors, where transformation occurs by the action of engineered stresses in thin cantilevers or sheets. The required forces can arise from three main sources: capillarity, − thin-film residual stresses, − and active (i.e., stimuli-responsive) materials. ,− As an example of the first, heating of a metal solder (e.g., Sn, Pb–Sn) patterned along lines above its melting point leads to a change of shape to minimize its surface energy, resulting in folding or locking processes. , Figure e presents a submillimeter-scale polyhedron created by this type of self-folding assembly with an algorithmic design . Melting of electrodeposited solders (Pb–Sn; melting temperature 183 °C) on polygonal Ni panels moves hinges for each panel and results in self-folding at the edges of the 2D nets to create a self-assembled 3D geometry (1 mm height for the smallest feature).…”

Section: Three-dimensional Neural Interfacesmentioning

confidence: 99%

“…Three-dimensional assembly induced by thin-film residual stresses uses mismatches in mechanical strains of stacked thin films (e.g., Si x N y , ZnO, TiO 2 , Al 2 O 3 , GaAs, Cr, vanadium dioxide (VO 2 ), germanium (Ge)). ,, Such multilayers can be prepared on substrates with sacrificial layers that, upon their removal, lead to self-rolling to form tubular, scroll-like, or polyhedral geometries. This process can transform microfabricated 2D electronic structures into 3D geometries for various applications (e.g., energy, , optoelectronics, , electronics, ,− biological studies − ). Thin, tubular SiNM-based photodetectors exhibit 1000 times enhancements in photoresponsivity compared to 2D devices due to light-trapping effects.…”

Section: Three-dimensional Neural Interfacesmentioning

confidence: 99%

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Materials Chemistry of Neural Interface Technologies and Recent Advances in Three-Dimensional Systems

et al. 2021

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Advances in materials chemistry and engineering serve as the basis for multifunctional neural interfaces that span length scales from individual neurons to neural networks, neural tissues, and complete neural systems. Such technologies exploit electrical, electrochemical, optical, and/or pharmacological modalities in sensing and neuromodulation for fundamental studies in neuroscience research, with additional potential to serve as routes for monitoring and treating neurodegenerative diseases and for rehabilitating patients. This review summarizes the essential role of chemistry in this field of research, with an emphasis on recently published results and developing trends. The focus is on enabling materials in diverse device constructs, including their latest utilization in 3D bioelectronic frameworks formed by 3D printing, self-folding, and mechanically guided assembly. A concluding section highlights key challenges and future directions.

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Section: Three-dimensional Neural Interfacesmentioning

confidence: 99%

Section: Three-dimensional Neural Interfacesmentioning

confidence: 99%

Materials Chemistry of Neural Interface Technologies and Recent Advances in Three-Dimensional Systems

et al. 2021

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Hexahedral LED Arrays with Row and Column Control Lines Formed by Selective Liquid‐Phase Plasticization and Nondisruptive Tucking‐Based Origami

Kim

Yoo

et al. 2020

Adv Materials Technologies

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Origami/kirigami of flexible electronics is a promising way to produce 3D electronics because well‐developed silicon‐based technologies can be used for the planar circuitry layout. However, it is still a challenge to enable general row and column control lines to develop 3D addressable sensory and display systems. This study addresses this issue via selective plasticization of an acrylonitrile butadiene styrene (ABS) film with N,N‐dimethylformamide (DMF) through polydimethylsiloxane (PDMS) microfluidic channels. The use of DMF provides plasticization in a controllable manner because of the fast absorption of the DMF in the liquid phase during the plasticization process, a prolonged retention time of DMF in the ABS film at room temperature during the transformation process, and fast desorption at 60– 80 °C for the deplasticization process. The use of microfluidic channels allows high‐resolution selective plasticization to enable extreme cases of local bending or even folding inward and outward, thereby enabling tucking‐based origami with no crack generation. The lamination of membrane‐type electronic devices to an ABS film followed by selective plasticization and transformation enables nondisruptive tucking‐based origami at the electronics level, such as for the demonstration of a hexahedral light‐emitting diode (LED) array with general row and column control lines.

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Three‐Dimensional Transformation of Membrane‐Type Electronics Using Transient Microfluidic Channels for the Sequential Selective Plasticization of Supportive Plastic Substrates

Cha

Kim

et al. 2022

Adv Materials Technologies

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This study demonstrates a technique for the development of 3D electronics based on planar membrane‐type devices and a supportive plastic (e.g., acrylonitrile butadiene styrene [ABS] used in this study) substrate containing internal microfluidic channels (µ‐FCs) that allow selective plasticization and transformation after the insertion of a liquid plasticizer (e.g., N,N‐dimethylformamide). The internal µ‐FC has a strong advantage of transiency and does not require an additional removal process because the channels are self‐closed by the swelling and dissolution of the plasticized regions. Furthermore, the 3D printing process to create internal µ‐FCs provides a considerable amount of freedom in channel design for sequential plasticization and transformation into complex structures. Using this method, extreme scenarios that involve complete bending of the metal electrodes and indium gallium zinc oxide thin‐film transistors laminated to the ABS substrates without electrical failure are possible, regardless of the bending direction and the vertical position of the electrode of the plastic substrate. Finally, a truncated octahedral light‐emitting diode display is successfully developed by multiple cycles of sequential plasticization and transformation processes to demonstrate the feasibility of this method.

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Automatic Transformation of Membrane‐Type Electronic Devices into Complex 3D Structures via Extrusion Shear Printing and Thermal Relaxation of Acrylonitrile–Butadiene–Styrene Frameworks

Cited by 5 publications

References 55 publications

Materials Chemistry of Neural Interface Technologies and Recent Advances in Three-Dimensional Systems

Materials Chemistry of Neural Interface Technologies and Recent Advances in Three-Dimensional Systems

Hexahedral LED Arrays with Row and Column Control Lines Formed by Selective Liquid‐Phase Plasticization and Nondisruptive Tucking‐Based Origami

Three‐Dimensional Transformation of Membrane‐Type Electronics Using Transient Microfluidic Channels for the Sequential Selective Plasticization of Supportive Plastic Substrates

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