All-2D Material Inkjet-Printed Capacitors: Toward Fully Printed Integrated Circuits

Worsley, Robyn; Pimpolari, Lorenzo; McManus, Daryl; Ge, Ning; Ionescu, Robert; Wittkopf, Jarrid A.; Alieva, Adriana; Basso, Giovanni; Macucci, Massimo; Iannaccone, Giuseppe; Novoselov, Kostya S.; Holder, Helen; Fiori, Gianluca; Casiraghi, Cinzia

doi:10.1021/acsnano.8b06464

Cited by 105 publications

(121 citation statements)

References 44 publications

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“…Over the past decade, nanoscience has dominated the landscape of research. From electronics [1][2][3][4], energy storage [5][6][7][8] to bioengineering [9][10][11][12], its profound influence in driving forward innovation has been felt in every corner of science. Recently, nanoscience and more specifically composites filled with nanomaterials, has drawn the attention of many researchers as tactile and health sensors due to them possessing sensitivities which far surpass that of current commercial sensing devices.…”

Section: Introductionmentioning

confidence: 99%

Stumbling through the Research Wilderness, Standard Methods To Shine Light on Electrically Conductive Nanocomposites for Future Healthcare Monitoring

Boland

2019

ACS Nano

144

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Electrically conductive nanocomposites are an exciting ever-expanding area of research that has yielded many new technologies for wearable health devices. Acting as strain sensing materials, they have paved the way towards real-time medical diagnostic tools that may very well lead to a golden age of healthcare. Currently, the goal in research is to create a material that simultaneously has both a large gauge factor (G) and sensing range. However, a weakness in the area of electromechanical research is the lack of standardisation in the reporting of the figure of merit (i.e. G) and the need for new metrics to give researchers a more complete view of the research landscape of resistive-type sensors. A paradigm shift in the way in which data is reported is required, to push research in the right direction and to facilitate achieving research goals. Here, we report a standardised method for reporting strainsensing performance and the introduction of the working factor (W) and the Young's modulus (Y) of a material as two new material criteria. Using this new method, we can now for the first time define the benchmarks for an optimum sensing material (G > 7, W > 1, Y < 300 kPa) using limits set by standard commercial materials and the human body. Using extrapolated data from 200 publications normalised to this standard method, we can review what composite-types meet these benchmark limits, what governs composite performances, the literary trends in composites and individual nanomaterial performance and the future prospects of research.

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Section: Introductionmentioning

confidence: 99%

Stumbling through the Research Wilderness, Standard Methods To Shine Light on Electrically Conductive Nanocomposites for Future Healthcare Monitoring

Boland

2019

ACS Nano

144

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“…[165,166] Due to attributes such as non-contact, maskless, and additive patterning, inkjet printing has been widely applied to fabricate flexible devices, such as thin-film transistors, [167][168][169] solar cells, [170][171][172] and supercapacitors (SCs). [107,173,174] Printing resolution is critical for practical applications, especially for printed electronics, where a high printing resolution could minimize the device footprint for enhanced performance and integration complexity. [74,133,150] The printing resolution of an inkjet printing process is primarily limited by how a droplet spreads on a substrate during the solvent evaporation and how such spreading changes with the overlap of adjacent drops to form continuous features.…”

Section: Inkjet Printingmentioning

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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“…On the other hand, liquid phase deposition techniques such as inkjet‐printing and spray‐coating using dispersion of nanosheet‐type 2D BN were also considered. [ 25,26 ] These methods offer good thickness scalability, substrate variety, low processing temperature, and cost effectiveness. However, solution‐deposited BN films usually lack sufficient uniformity and adhesion quality due to the solute redistribution [ 27,28 ] and morphology distortion of the BN nanosheets.…”

Section: Figurementioning

confidence: 99%

Desolvation‐Triggered Versatile Transfer‐Printing of Pure BN Films with Thermal–Optical Dual Functionality

Han

Rah

et al. 2020

Advanced Materials

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Although hexagonal boron nitride (BN) nanostructures have recently received significant attention due to their unique physical and chemical properties, their applications have been limited by a lack of processability and poor film quality. In this study, a versatile method to transfer‐print high‐quality BN films composed of densely stacked BN nanosheets based on a desolvation‐induced adhesion switching (DIAS) mechanism is developed. It is shown that edge functionalization of BN sheets and rational selection of membrane surface energy combined with systematic control of solvation and desolvation status enable extensive tunability of interfacial interactions at BN–BN, BN–membrane, and BN–substrate boundaries. Therefore, without incorporating any additives in the BN film and applying any surface treatment on target substrates, DIAS achieves a near 100% transfer yield of pure BN films on diverse substrates, including substrates containing significant surface irregularities. The printed BNs demonstrate high optical transparency (>90%) and excellent thermal conductivity (>167 W m−1 K−1) for few‐micrometer‐thick films due to their dense and well‐ordered microstructures. In addition to outstanding heat dissipation capability, substantial optical enhancement effects are confirmed for light‐emitting, photoluminescent, and photovoltaic devices, demonstrating their remarkable promise for next‐generation optoelectronic device platforms.

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All-2D Material Inkjet-Printed Capacitors: Toward Fully Printed Integrated Circuits

Cited by 105 publications

References 44 publications

Stumbling through the Research Wilderness, Standard Methods To Shine Light on Electrically Conductive Nanocomposites for Future Healthcare Monitoring

Stumbling through the Research Wilderness, Standard Methods To Shine Light on Electrically Conductive Nanocomposites for Future Healthcare Monitoring

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

Desolvation‐Triggered Versatile Transfer‐Printing of Pure BN Films with Thermal–Optical Dual Functionality

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