2021
DOI: 10.1007/s12274-021-3388-x
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Functional photonic structures for external interaction with flexible/wearable devices

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Cited by 13 publications
(4 citation statements)
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References 183 publications
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“…Flexible wearable devices have attracted great interest for their applications in health management, instant communication, and thermoregulation due to their miniaturization, integration and intelligence . However, various high-frequency and high-power electronics integrated into confined spaces may lead to severe overheating problems, resulting in energy consumption, aging, and reduced user comfort.…”
Section: Energy-efficient and Smart Applicationsmentioning
confidence: 99%
“…Flexible wearable devices have attracted great interest for their applications in health management, instant communication, and thermoregulation due to their miniaturization, integration and intelligence . However, various high-frequency and high-power electronics integrated into confined spaces may lead to severe overheating problems, resulting in energy consumption, aging, and reduced user comfort.…”
Section: Energy-efficient and Smart Applicationsmentioning
confidence: 99%
“…In particular, electrothermal elastomers can be developed to extend their service life by introducing hydrogen bonds, [31] ionic coordination bonds, [32] and dynamic covalent bonds. [33,34] Among them, photonic vitrimer elastomers based on dynamic covalent bond exhibit creepresistance, high mechanical strength, and self-healing capability, providing a promising strategy for intelligent wearable devices [35] and visualized force sensors. [36] Herein, we present the rational design and fabrication of a mechanochromic and self-healable flexible wireless thermal management device through dynamic covalent bond.…”
Section: Introductionmentioning
confidence: 99%
“…To address this issue, self‐healing photonic elastomers can be developed to extend their service life by introducing hydrogen bonds, [ 31 ] ionic coordination bonds, [ 32 ] and dynamic covalent bonds. [ 33,34 ] Among them, photonic vitrimer elastomers based on dynamic covalent bond exhibit creep‐resistance, high mechanical strength, and self‐healing capability, providing a promising strategy for intelligent wearable devices [ 35 ] and visualized force sensors. [ 36 ]…”
Section: Introductionmentioning
confidence: 99%
“…Many of the papers feature the role of light and optics in advanced nanosystems. A comprehensive review article by Prof. Cunjiang Yu (a former postdoctoral fellow) and his students at the University of Houston summarizes the stateof-the-art in flexible photovoltaic devices as power sources for skin-mounted electronic devices [1]; as a complement to this piece on interactions with ambient light, Prof. Young Min Song (a former postdoctoral fellow) and his group at Gwanju Institute of Science and Technology (GIST) describe bio-integrated platforms that use light to probe body processes [2]; Prof. Xing Sheng (a former postdoctoral fellow) writes with his students at Tsinghua University on monolithically integrated microscale components that emit and detect light using photon recycling concepts with unique capabilities in characterizing soft biological tissues, such as the skin [3]; generation and detection of light using flexible/stretchable platforms are important in this broader context, as highlighted in an article by Prof. Dae-Hyeong Kim (a former PhD student and postdoctoral fellow) and his group at Seoul National University [4]; as the basis for sophisticated methods for electronic sensing of light, Prof. Sung Hun Jin (a former postdoctoral fellow) and his students at Incheon National University describe the latest progress in two-dimensional (2D) nanomaterials for converting light to frequency modulated electronic signals [5] and, in a separate article, recent work on high performance transistors for controlling microscale lightemitting diodes (LEDs) and other components [6]; Prof. Seokwoo Jeon (one of our first PhD students) and his group at the Korean Advanced Institute for Science and Technology (KAIST) write about powerful approaches that exploit light to fabricate complex nanostructures, including those at large-scales and in threedimensional (3D) configurations [7]; in terms of unusual optical nanomaterials by chemical synthesis, Prof. Yugang Sun (a former postdoctoral fellow) and his students at Temple University describe methods for forming silica layers on titania nanoparticles to control their plasmonic properties through nitridation [8]; in work that shares some common chemistry concepts, Prof. Yujie Xiong (a former postdoctoral fellow) at University of Science and Technology of China (USTC) describes in an article co-authored with his students the use of carbon nanomaterials as catalysts in nitrogen reduction reactions [9].…”
mentioning
confidence: 99%