Wearable multifunctional printed graphene sensors

Kaidarova, Altynay; Khan, M. A.; Marengo, Marco; Swanepoel, Liam; Przybysz, Alexander; Muller, Cobus; Fahlman, Andreas; Büttner, U.; Geraldi, Nathan R.; Wilson, Rory P.; Duarte, Carlos M.; Kosel, Jürgen

doi:10.1038/s41528-019-0061-5

Cited by 110 publications

(77 citation statements)

References 68 publications

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“…This can further improve the possibility of practical application of wearable electronic devices. Integration with various types of sensors As mentioned above, MSCs can be used to power various types of sensors, and their integration can be applied in many fields 128,129 . For example, MSCs coupled with gas sensor can monitor the change of surrounding gas in real time, which is of great significance to control environmental quality and human health.…”

Section: Energy Storagementioning

confidence: 99%

Recent developments of advanced micro-supercapacitors: design, fabrication and applications

et al. 2020

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The rapid development of wearable, highly integrated, and flexible electronics has stimulated great demand for on-chip and miniaturized energy storage devices. By virtue of their high power density and long cycle life, micro-supercapacitors (MSCs), especially those with interdigital structures, have attracted considerable attention. In recent years, tremendous theoretical and experimental explorations have been carried out on the structures and electrode materials of MSCs, aiming to obtain better mechanical and electrochemical properties. The high-performance MSCs can be used in many fields, such as energy storage and medical assistant examination. Here, this review focuses on the recent progress of advanced MSCs in fabrication strategies, structural design, electrode materials design and function, and integrated applications, where typical examples are highlighted and analyzed. Furthermore, the current challenges and future development directions of advanced MSCs are also discussed.

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Section: Energy Storagementioning

confidence: 99%

Recent developments of advanced micro-supercapacitors: design, fabrication and applications

et al. 2020

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“…[ 3,4 ] Recently, a series of materials, e.g., carbon nanotubes, graphene, metal nanowires, and conducting polymers, have been widely employed as flexible conductors. [ 5,6 ] Compared to traditional metal or metal oxide electrodes, carbon‐based films as both bottom and top electrodes for metal‐free electronics not only ensure the intrinsical flexibility of device, but also avoid the filamentary conduction which results from the diffusion of metal atoms into intermedium active layers. [ 7–9 ] However, most of the previously reported carbon‐based flexible memory devices are containing a metal electrode as either bottom or top electrode.…”

Section: Figurementioning

confidence: 99%

Flexible Metal‐Free Memory Electronic Made of π‐Conjugation‐Interrupted Hyperbranched Polymer Switch and Reduced Graphene Oxide Electrodes

Liu

Song

Yin

et al. 2020

Macro Materials & Eng

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A flexible metal‐free flash memory device with reduced graphene oxide films as electrodes and diarylfluorene‐based π‐conjugation‐interrupted hyperbranched polymers (CIHPs) as active switches is reported. Two CIHPs, named PCzPF and PCzPF‐PF, are synthesized via BF3•Et2O‐catalyzed fluorenol’s Friedel–Crafts reaction, where the PCzPF‐PF is designed by the decoration of hindrance functional groups, i.e., bulky 9‐phenyl‐fluorenyl (PF) moieties, at the end‐groups of PCzPF. Both of the two CIHPs exhibit excellent solubility and thermal stability. The PCzPF‐based device exhibits no switching effect while the PCzPF‐PF‐based device shows a flash type memory effect, indicating the incorporation of PF groups plays a critical role in realizing electrically bistable behaviors. In particular, the optimized memory exhibits a high ON/OFF ratio of > 3.0 × 103, long retention time of up to 1.2 × 104 s, and high mechanical stability. This work opens a new avenue for metal‐free memory electronics through a low‐cost and full‐solution process approach.

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“…Since then, this so‐called laser‐induced graphene (LIG) has been utilized to create numerous electronic devices in a single step. [ 16–20 ] In the present study, we demonstrate the use of LIG to fabricate piezoresistive, mechanically flexible, lightweight, and robust pressure sensors with a large measurement range, thereby offering promise across the whole spectrum of demands for pressure sensors.…”

Section: Introductionmentioning

confidence: 99%

Laser‐Printed, Flexible Graphene Pressure Sensors

et al. 2020

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While the outstanding properties of graphene have attracted a lot of attention, one of the major bottlenecks of its widespread usage is its availability in large volumes. Laser printing graphene on polyimide films is an efficient single‐step fabrication process that can remedy this issue. A laser‐printed, flexible pressure sensor is developed utilizing the piezoresistive effect of 3D porous graphene. The pressure sensors performance can be easily adjusted via the geometrical parameters. They have a sensitivity in the range of 1.23 × 10−3 kPa and feature a high resolution with a detection limit of 10 Pa in combination with an extremely wide dynamic range of at least 20 MPa. They also provide excellent long‐term stability of at least 15 000 cycles. The biocompatibility of laser‐induced graphene is also evaluated by cytotoxicity assays and fluorescent staining, which show an insignificant drop in viability. Polymethyl methacrylate coating is particularly useful for underwater applications, protecting the sensors from biofouling and shunt currents, and enable operation at a depth of 2 km in highly saline Red Sea water. Due to its features, the sensors are a prime choice for multiple healthcare applications; for example, they are used for heart rate monitoring, plantar pressure measurements, and tactile sensing.

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Wearable multifunctional printed graphene sensors

Cited by 110 publications

References 68 publications

Recent developments of advanced micro-supercapacitors: design, fabrication and applications

Recent developments of advanced micro-supercapacitors: design, fabrication and applications

Flexible Metal‐Free Memory Electronic Made of π‐Conjugation‐Interrupted Hyperbranched Polymer Switch and Reduced Graphene Oxide Electrodes

Laser‐Printed, Flexible Graphene Pressure Sensors

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