Rolled‐up Nanotechnology: Materials Issue and Geometry Capability

Xu, Changhao; Wu, Xiang; Huang, Gaoshan; Mei, Yongfeng

doi:10.1002/admt.201800486

Cited by 45 publications

(37 citation statements)

References 261 publications

(448 reference statements)

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“…With the help of compatible lithographic techniques and, more importantly, development of novel lithographically processable strain‐engineering materials and composites, the self‐assembly of micro‐ and nanoscale 3D architectures can be obtained by the shaping of initially planar structures . These shapeable material technologies have already demonstrated (Figure b) the capability to self‐assemble planar films into a number of different complex polygonal structures and tubular “Swiss‐rolls.”…”

Section: Introductionmentioning

confidence: 99%

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

Karnaushenko

Kang

Schmidt

2019

Adv Materials Technologies

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simple transistors and logics to highly integrated microcontrollers and displays, the latter of which utilizes some of the most technologically advanced processes available in the industry. [3] The success of these technologies has been achieved through enhanced integration of various active functional blocks such as transistors, digital logics, and analog circuits, along with advances in miniaturization and simplification of the overall manufacturing process, eventually leading to large scale, parallel fabrication of silicon chip-based microelectronic components and systems. [4,5] However, many of the manufacturing steps in assembling these electronic components remain either semiparallel or sequential in nature, including processes as dicing, pick and place, packaging, and final assembly of the device. Each additional sequential step increases costs and should ideally be avoided, however substantial streamlining is not always feasible in complex manufacturing processes. [6] More critically, highly integrated silicon-based devices still require several external supporting components for their operation such as wiring, powering, sensing, and communications that cannot be easily integrated within the planar surface of a silicon die. Thus, sensors, actuators, capacitors, coils, antennas, and optics, each crucial for the complete system, are typically placed separately from the silicon chip onto a printed circuit board (PCB), or integrated within another package (Figure 1a). While the need for ever decreasing sizes has demanded tremendous investments and efforts in the manufacture of completed assemblies, the miniaturizing of 3D electronic components (Figure 1b) and systems has nevertheless reached the range of mesoscopic sizes (<1 mm) where the manufacture and assembly of components experience challenges with respect to yield, costs, and reliability. [7] As a result, these issues limit the fabrication potential and commercial viability of components and systems to scales around 1 mm, [8] and despite efforts to improve the planar construction of mesoscopic 3D devices, the results are seen as inefficient and experience difficulties in achieving high performances while maintaining reasonable complexity. Despite the great success in manufacturing active electronics, such concerns are strongly related to the fabrication of passive electronic components like inductors, capacitors, antennas, and resonators where material properties (e.g., mechanical, magnetic, and electrical) and geometry play a crucial role. [8,9] In order to downscale these devices further and improve integration with active electronics, novel fabrication strategies are required.Electronic devices and their components are continually evolving to offer improved performance, smaller sizes, lower weight, and reduced costs, often requiring the state-of-the-art manufacturing and materials to do so. An emerging class of materials and fabrication techniques inspired by self-assembling biological systems shows promise as an alternative to the more traditional m...

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Section: Introductionmentioning

confidence: 99%

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

Karnaushenko

Kang

Schmidt

2019

Adv Materials Technologies

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“…Complex 3D functional systems are of widespread interest due to their potential applications in areas ranging from biomedical devices and metamaterials to electronic platforms . Although fabrication techniques based on 3D printing, templated growth, and controlled folding/rolling are useful in many contexts, each has limitations in materials compatibility, accessible feature size or, most critically, alignment with state‐of‐the‐art 2D processing techniques used in the semiconductor industry. A portfolio of recently presented methods allow geometric transformation of such 2D systems (referred to here as 2D precursors) into 3D structures by the action of compressive forces delivered at precisely defined locations via a prestretched silicone elastomer substrate .…”

Section: Introductionmentioning

confidence: 99%

Transformable, Freestanding 3D Mesostructures Based on Transient Materials and Mechanical Interlocking

Park

Luan

Kwon

et al. 2019

Adv Funct Materials

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Areas of application that span almost every class of microsystems technology, from electronics to energy storage devices to chemical/biochemical sensors, can benefit from options in engineering designs that exploit 3D micro/nanostructural layouts. Recently developed methods for forming such systems exploit stress release in prestretched elastomer substrates as a driving force for the assembly of 3D functional microdevices from 2D precursors, including those that rely on the most advanced functional materials and device designs. Here, concepts that expand the options in this class of methods are introduced, to include 1) component parts built with physically transient materials to allow triggered transformation of 3D structures into other shapes and 2) mechanical interlocking elements composed of female‐type lugs and male‐type hooks that activate during the assembly process to irreversibly “lock‐in” the 3D shapes. Wireless electronic devices demonstrate the utility of these ideas in functional systems.

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“…The materials and techniques necessary for self‐assembly on the mesoscopic scale has progressed rapidly over the last two decades, and it has certainly experienced an increased level of interest in the past few years as is evident from the recent proliferation of reviews on the topic . The techniques associated with self‐assembled devices as well as their material platforms are reviewed in this section to bring the various parts of the self‐assembly toolbox to the readers' attention.…”

Section: D Self‐assembled Microelectronic Technologies and Materialsmentioning

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: Materials Issue and Geometry Capability

Cited by 45 publications

References 261 publications

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

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

Transformable, Freestanding 3D Mesostructures Based on Transient Materials and Mechanical Interlocking

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

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