An Intrinsically Stretchable High‐Performance Polymer Semiconductor with Low Crystallinity

Zheng, Yu; Wang, Ging Ji Nathan; Kang, Jiheong; Nikolka, Mark; Wu, Hung Chin; Tran, Helen; Song, Zhanqian; Yan, Hongping; Hu, Chen; Yuen, Pong Mo; Mun, Je Ho; Dauskardt, Reinhold H.; McCulloch, Iain; Tok, Jeffrey B.‐H.; Gu, Xiaodan; Bao, Zhenan

doi:10.1002/adfm.201905340

Cited by 128 publications

(225 citation statements)

References 72 publications

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“…[ 1–5 ] Continuous monitoring of typical physiological data such as respiration rate, heart rate, contraction/expansion of muscles, and ground reaction forces through the sensors is particularly important for the understanding of human physiology and phenotypes that lead from health to diseases ( Scheme a). [ 6–10 ] One of the fundamental units of wearable electronics is a stretchable display that simultaneously visualizes signals from the “bodyNet” and provides feedback to the system. [ 11–16 ] However, existing organic and quantum‐dot (QD) light‐emitting devices are degraded by various molecular interactions with oxygen and water.…”

Section: Methodsmentioning

confidence: 99%

Water Passivation of Perovskite Nanocrystals Enables Air‐Stable Intrinsically Stretchable Color‐Conversion Layers for Stretchable Displays

et al. 2020

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Conventional organic light‐emitting devices without an encapsulation layer are susceptible to degradation when exposed to air, so realization of air‐stable intrinsically‐stretchable display is a great challenge because the protection of the devices against penetration of moisture and oxygen is even more difficult under stretching. An air‐stable intrinsically‐stretchable display that is composed of an intrinsically‐stretchable electroluminescent device (SELD) integrated with a stretchable color‐conversion layer (SCCL) that contains perovskite nanocrystals (PeNCs) is proposed. PeNCs normally decay when exposed to air, but they become resistant to this decay when dispersed in a stretchable elastomer matrix; this change is a result of a compatibility between capping ligands and the elastomer matrix. Counterintuitively, the moisture can efficiently passivate surface defects of PeNCs, to yield significant increases in both photoluminescence intensity and lifetime. A display that can be stretched up to 180% is demonstrated; it is composed of an air‐stable SCCL that down‐converts the SELD’s blue emission and reemits it as green. The work elucidates the basis of moisture‐assisted surface passivation of PeNCs and provides a promising strategy to improve the quantum efficiency of PeNCs with the aid of moisture, which allows PeNCs to be applied for air‐stable stretchable displays.

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Section: Methodsmentioning

confidence: 99%

Water Passivation of Perovskite Nanocrystals Enables Air‐Stable Intrinsically Stretchable Color‐Conversion Layers for Stretchable Displays

et al. 2020

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“…Interestingly, polymers based on the extended fused-ring IDT core display high FET mobilities with high backbone coplanarity despite the lack of long-range crystalline order in the solid state. 2,3,[25][26][27][28] This intriguing feature considerably differs from the abovementioned theory and provides a new molecular-design guideline for achieving high mobilities in near-amorphous polymers, thus facilitating the development of intrinsically stretchable semiconducting polymers toward next-generation electronics. Driven by their unique, yet different properties, many polymers based on CDT and IDT units have been incorporated into high-performance FETs and continue to be studied (see Fig.…”

Section: Introductionmentioning

confidence: 93%

“…π-conjugated polymers have been extensively studied for their application in printing organic eld-effect transistor (FET) arrays and circuits to realize low-cost, large-area, exible, and even stretchable nextgeneration electronics that cannot be realized using traditional silicon technologies. [1][2][3][4][5][6][7] On the basis of the principle that charge carrier mobility is unambiguously linked to the degree of order in the packing, more than a decade of research has focused on increasing the crystallinity of π-conjugated polymers as a strategy for improving charge transport; this has reliably boosted mobility to exceed 10 cm 2 V − 1 s − 1 . 8−13 Three major design strategies exist for enforcing polymer crystallinity: (i) donor-acceptor architecture in the backbone induces a strong intramolecular charge transfer (ICT) effect as an attractive force between the donor and acceptor units, resulting in a more planar con guration that facilitates πelectron delocalization along the backbone; [14][15][16][17] (ii) the incorporation of fused aromatic building segments into the backbone generates a large π-orbital overlapping area, formulating large crystalline domains with only few disordered domain boundaries; 12, 18−21 and (iii) a precise regioregularity in the polymer repeating units realizes enhanced structural arrangement of the chains, thus promoting selforganization.…”

Section: Introductionmentioning

confidence: 99%

WITHDRAWN: Near 14 cm2 V-1 s-1 Charge Carrier Mobility Enabled by Amorphous Indacenodithiophene-based Polymers with Controlled Regioregularity

Cho¹,

Park²,

Jeong³

et al. 2020

Preprint

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Herein, we report the synthesis and characterization of four regioregular, well-defined donor–acceptor polymers (P1, P2, P3, and P4), comprising different compositions of axisymmetric cyclopentadithiophene (CDT) and centrosymmetric indacenodithiophene (IDT) donors in conjugation with the asymmetric 5-fluoro-2,1,3-benzothiadiazole acceptor that is precisely oriented in the regular pattern along the backbone. Morphological analyses of the above polymer series show that exclusive CDT donor-containing P1 is semicrystalline, whereas the others (IDT donor-containing ones) are near-amorphous in nature. Comparatively, IDT donor-containing polymers have superior hole mobilities; in particular, exclusive IDT donor-containing polymer P4 offers an ultra-high mobility of 13.82 cm2 V− 1 s− 1 at a channel length of 200 µm, which is comparable to the recently reported values for state-of-the-art semicrystalline semiconductors. In addition, the near-amorphous characteristics render the IDT donor-containing polymer films highly ductile and stretchable. Such superior features, which are associated with excellent charge transport and ductility, demonstrate a promising possibility for application in viable stretchable electronics.

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“…[911] Many recent studies have focused on the innovation of intrinsically stretchable materials, such as semiconductors and dielectrics, for high-performance-printed stretchable thin-film transistors. [400,444,609,[912][913][914] For instance, Wang et al reported an intrinsically stretchable transistor array for signal manipulation and computation. [271] The SEBS, 'conjugated polymer/elastomer phase separation induced elasticity' (CONPHINE) film, and CNTs were used as the dielectric, semiconductor, and electrodes, respectively.…”

Section: Transistorsmentioning

confidence: 99%

Ink‐Based Additive Nanomanufacturing of Functional Materials for Human‐Integrated Smart Wearables

2020

Advanced Intelligent Systems

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Human-integrated devices include wearable and implantable devices for monitoring vital human signals or interacting with the human body. [1-3] The human-integrated devices needed to be tethered to the organs or the human skin for implementing their functions such as sensing and energy harvesting. [4-18] The economical, agile, customizable manufacturing, and integration of multifunctional device modules into networked systems with mechanical compliance and robustness will enable unprecedented human-integrated smart wearables [19-23] and usher in exciting opportunities in emerging technologies such as electronics, [24-29] wearable computation, [30-36] human-machine interface, [37-42] robotics, [43-48] and advanced healthcare. [49-54] The fabrication of stateof-the-art microelectronics involves hightemperature processing steps, which are generally incompatible with the flexible substrates (e.g., paper, polymer, fiber, etc.) [55-61] widely used in the wearable devices. Moreover, the current microfabrication technologies are not well positioned to process the emerging functional nanomaterials (e.g., nanowires [NWs] and 2D materials). [62-65] Such incomparability severely limits the pace of deploying these emerging materials (despite their unprecedented properties) in wearable and flexible device technologies. The additive manufacturing (AM) processes have emerged as potential candidates for addressing the earlier limitations of the current microfabrication technologies in fabricating flexible/wearable printed devices with diversified functionalities, e.g., energy harvesting/storage, sensing, actuation, and computation, leveraging advantages such as maskless processing, versatile ink formulation, low cost, low processing temperature, and scalability. [66-71] Researchers have devoted tremendous efforts to develop the related technologies, and several reviews have provided excellent discussions on the material formulation and process aspects of AM techniques. [63,72-79] However, to our best knowledge, there are few review reports about the ink-based additive nanomanufacturing of functional materials for human-integrated smart wearables. To fill this gap, here we review the recent progress in ink-based

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An Intrinsically Stretchable High‐Performance Polymer Semiconductor with Low Crystallinity

Cited by 128 publications

References 72 publications

Water Passivation of Perovskite Nanocrystals Enables Air‐Stable Intrinsically Stretchable Color‐Conversion Layers for Stretchable Displays

Water Passivation of Perovskite Nanocrystals Enables Air‐Stable Intrinsically Stretchable Color‐Conversion Layers for Stretchable Displays

WITHDRAWN: Near 14 cm2 V-1 s-1 Charge Carrier Mobility Enabled by Amorphous Indacenodithiophene-based Polymers with Controlled Regioregularity

Ink‐Based Additive Nanomanufacturing of Functional Materials for Human‐Integrated Smart Wearables

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