Anisotropic Thermal Conductive Composite by the Guided Assembly of Boron Nitride Nanosheets for Flexible and Stretchable Electronics

Hong, Haeleen; Jung, Yei Hwan; Lee, Ju Seung; Jeong, Chanseok; Kim, Jong Uk; Lee, Sori; Ryu, Hyewon; Kim, Heyn; Ma, Zhenqiang; Kim, Tae‐il

doi:10.1002/adfm.201902575

Cited by 164 publications

(110 citation statements)

References 34 publications

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“…Figure 5B)-unlike the case for traditional rigid inclusions. [141,142,[142][143][144][145] For improving thermal properties, LMs are desirable due to their high thermal conductivities relative to other liquids (see section 3.1) [3,70,85,[146][147][148][149] (c.f. Figure 5D).…”

Section: Electrical Thermal and Magnetic Propertiesmentioning

confidence: 99%

Solid–Liquid Composites for Soft Multifunctional Materials

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Tutika

Kim

et al. 2020

Adv Funct Materials

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Soft materials with a liquid component are an emerging paradigm in materials design. The incorporation of a liquid phase, such as water, liquid metals, or complex fluids, into solid materials imparts unique properties and characteristics that emerge as a result of the dramatically different properties of the liquid and solid. Especially in recent years, this has led to the development and study of a range of novel materials with new functional responses, with applications in topics including soft electronics, soft robotics, 3D printing, wet granular systems and even in cell biology. Here we provide a review of solid-liquid composites, broadly defined as a material system with at least one, phase-separated liquid component, and discuss their morphology and fabrication approaches, their emergent mechanical properties and functional response, and the broad range of their applications.

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Section: Electrical Thermal and Magnetic Propertiesmentioning

confidence: 99%

Solid–Liquid Composites for Soft Multifunctional Materials

Style

Tutika

Kim

et al. 2020

Adv Funct Materials

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“…With the rapid development of modern electronics, in particular with increasing power density and miniaturization of electronic devices, effective heat dissipation of such devices has become a critical limiting factor, because the generated undesirable heat may be concentrated in a specific area in the devices and causes the thermal failure. In an individual device, heat from an electronic component can disturb the nearby ones 55 . To evaluate the heat-dissipating characteristics of the stretchable strain sensors, thermal conductivity of the samples, including the TPU-BNNS film with BNNS contents of 25 wt%, 30 wt%, and 35 wt%, the pure TPU film, and the whole strain sensor, was measured and compared.…”

Section: Resultsmentioning

confidence: 99%

A high performance wearable strain sensor with advanced thermal management for motion monitoring

et al. 2020

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Resistance change under mechanical stimuli arouses mass operational heat, damaging the performance, lifetime, and reliability of stretchable electronic devices, therefore rapid thermal heat dissipating is necessary. Here we report a stretchable strain sensor with outstanding thermal management. Besides a high stretchability and sensitivity testified by human motion monitoring, as well as long-term durability, an enhanced thermal conductivity from the casted thermoplastic polyurethane-boron nitride nanosheets layer helps rapid heat transmission to the environments, while the porous electrospun fibrous thermoplastic polyurethane membrane leads to thermal insulation. A 32% drop of the real time saturated temperature is achieved. For the first time we in-situ investigated the dynamic operational temperature fluctuation of stretchable electronics under repeating stretching-releasing processes. Finally, cytotoxicity test confirms that the nanofillers are tightly restricted in the nanocomposites, making it harmless to human health. All the results prove it an excellent candidate for the next-generation of wearable devices.

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“…Further investigations on thermally conductive substrates with mechanical flexibility are on-going. [113,114] Promising results have been reported on improving the DC performance of GaN HEMTs. [115] However, whether these thermally improved substrates are suitable for GaN HEMT in microwave applications remains unknown.…”

Section: Flexible Microwave Transistors Based On Compound Semiconductorsmentioning

confidence: 99%

“…It is noted that research exploring flexible/stretchable substrates suitable for microwave applications are ongoing. [113,166,277,278] Before any breakthrough happens, inventing a strategy to enhance the thermal conductivity of the present flexible substrates may be an alternative route to a suitable solution for this challenge. It is also noted that there have been no demonstrations of stretchable active microwave electronic circuits on any stretchable substrates.…”

Section: Conclusion and Future Perspectivementioning

confidence: 99%

Flexible and Stretchable Microwave Electronics: Past, Present, and Future Perspective

Zhang

Lan

Qiu

et al. 2020

Adv Materials Technologies

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2000759 (6 of 38) www.advmattechnol.de Figure 4. Flexible microwave transistors. a) Schematic illustration of fabrication process flow of flexible microwave TFTs based on Si nanomembrane. Left, two-step transfer-printing of Si nanomembrane on flexible substrate with assist of PDMS stamp. Right, direct flip-printing Si nanomembrane on flexible substrate. Reproduced with permission. [72] Copyright 2010, Wiley-VCH. b) Flexible microwave Si TFT using direct flip-printing approach in (a). Reproduced under the terms of the Creative Commons Attribution 4.0 International License. [75] Copyright 2016, Springer Nature. c) Flexible microwave Si TFT using two-step approach in (a). Reproduced with permission. [72] Copyright 2010, Wiley-VCH. d) Cross-section SEM image of flexible Si MOSFET made by thinning a 65 nm node SOI wafer. Reproduced with permission. [45] Copyright 2013, American Institute of Physics. e) Optical images of flexible GaAs HBT on cellulose nanofibril (CNF) substrate. Reproduced under the terms of the Creative Commons Attribution 4.0 International License. [90] Copyright 2015, Springer Nature. f) Schematic illustration and normalized on-state conductance (G/G 0), maximum transconductance (g m /g m0) of flexible InAs MOSFET with self-aligned gate. Reproduced with permission. [53] Copyright 2012, American Chemical Society. g) Cross-section schematic illustration and gain curves of flexible InGaAs/InAlAs HEMT as function of frequency under various bending conditions. Reproduced with permission. [91] Copyright 2013, American Institute of Physics. h) Output power density (P OUT), power gain (G P) and power-added efficiency (PAE) of the flexible GaN HEMT on thermal conductive tape with thermal conductivity of 1.6 W m −1 K −1. Reproduced with permission. [92] Copyright 2017, Wiley-VCH. i) Photography of AlGaN/GaN film grown on BN coated sapphire substrate and printed on flexible tape. Reproduced with permission. [19] Copyright 2017, Wiley-VCH. j) Cross-section schematic illustration of bottom gate flexible graphene FET (GFET). Reproduced with permission. [93] Copyright 2013, American Chemical Society. k) Cross-section schematic illustration of top gate flexible GFET with self-aligned gate configuration. Reproduced with permission. [94] Copyright 2014, American Chemical Society. l) High-frequency characteristics of flexible GFET with gate length of 50 nm. Reproduced with permission. [95] Copyright 2018, Wiley-VCH. m) Schematic illustration and gain curves of flexible microwave transistor based on MoS 2 as function of frequency. Reproduced with permission. [96] Copyright 2014, Springer Nature. n) High-frequency characteristics of flexible microwave transistor based on black phosphorus (BP) as function of frequency. Reproduced with permission.

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Anisotropic Thermal Conductive Composite by the Guided Assembly of Boron Nitride Nanosheets for Flexible and Stretchable Electronics

Cited by 164 publications

References 34 publications

Solid–Liquid Composites for Soft Multifunctional Materials

Solid–Liquid Composites for Soft Multifunctional Materials

A high performance wearable strain sensor with advanced thermal management for motion monitoring

Flexible and Stretchable Microwave Electronics: Past, Present, and Future Perspective

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