Nanomesh pressure sensor for monitoring finger manipulation without sensory interference

Lee, Sung-Hoon; Franklin, Sae; Hassani, Faezeh Arab; Yokota, Tomoyuki; Nayeem, Md Osman Goni; Wang, Yan; Leib, Raz; Cheng, Gordon; Franklin, David W.; Someya, Takao

doi:10.1126/science.abc9735

Cited by 430 publications

(365 citation statements)

References 40 publications

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“…[ 30 ] In spite of this advantageous property—the air is easily available in environment, nevertheless, the flexible pressure sensors always should show excellent mechanical durability which increases the repeatability, and therefore, the sensor could sustain large amounts of pressure without degradation in its performance after multiple testing. The sensors with air dielectric gap always require mechanical support whenever the large area of diaphragm is chosen for designing large area sensor modules [ 131 ] otherwise the mechanically sensitive diaphragm is deflected at the center due to the prestress and gravity effect. [ 81,132 ] The major issue with air dielectric is that whenever the air particles squeeze after pressure application, damping is caused which degrades the performance of the sensors.…”

Section: Discussion On Various Design Approaches With Advantages Andmentioning

confidence: 99%

“…To overcome the challenges of the air dielectric based flexible capacitive pressure sensor, graphene, and graphene oxides and some porous materials including different porous elastomers, [ 28,90,93 ] sponge, [ 43,87 ] microfiber wipe, [ 43 ] nano‐mesh, [ 131 ] have been utilized as dielectrics. These porous materials include some amount of air either in bubble form or air molecules which are present between the threads or wires.…”

Section: Discussion On Various Design Approaches With Advantages Andmentioning

confidence: 99%

See 1 more Smart Citation

Recent Progress on Flexible Capacitive Pressure Sensors: From Design and Materials to Applications

Mishra

El‐Atab

Hussain

et al. 2021

Adv Materials Technologies

188

117

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For decades, the revolution in design and fabrication methodology of flexible capacitive pressure sensors using various inorganic/organic materials has significantly enhanced the field of flexible and wearable electronics with a wide range of applications in aerospace, automobiles, marine environment, robotics, healthcare, and consumer/portable electronics. Mathematical modelling, finite element simulations, and unique fabrication strategies are utilized to fabricate diverse shapes of diaphragms, shells, and cantilevers which function in normal, touch, or double touch modes, operation principles inspired from microelectromechanical systems (MEMS) based capacitive pressure sensing techniques. The capacitive pressure sensing technique detects changes in capacitance due to the deformation/deflection of a pressure sensitive mechanical element that alters the separation gap of the capacitor. Due to advancement in state‐of‐the‐art fabrication technologies, the performance and properties of capacitive pressure sensors are enhanced. In this review paper, recent progress in flexible capacitive pressure sensing techniques in terms of design, materials, and fabrication strategies is reported. The mechanics and fabrication steps of paper‐based low‐cost MEMS/flexible devices are also broadly reported. Lastly, the applications of flexible capacitive pressure sensors, challenges, and future perspectives are discussed.

show abstract

Section: Discussion On Various Design Approaches With Advantages Andmentioning

confidence: 99%

Section: Discussion On Various Design Approaches With Advantages Andmentioning

confidence: 99%

Recent Progress on Flexible Capacitive Pressure Sensors: From Design and Materials to Applications

Mishra

El‐Atab

Hussain

et al. 2021

Adv Materials Technologies

188

117

View full text Add to dashboard Cite

show abstract

“…Not included in this list, however, are imperceptible energy storage devices. Unlike other recently reported imperceptible electronics [ 4,5,7,13 ] where performance is minimally affected, reducing the thickness of energy storage devices to this level limits the mass loading of electrode materials, which is a big obstacle to achieve high area‐specific energy density. To our knowledge, among the thin electrodes [ 15–18 ] less than 1 μm, the recorded area‐specific energy density is only 2 mF cm −2 , [ 18 ] far below the requirement of practical application.…”

Section: Introductionmentioning

confidence: 91%

Imperceptible Supercapacitors with High Area‐Specific Capacitance

Jin

Zhu

Eisner

et al. 2021

Small

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Imperceptible electronics will make next‐generation healthcare and biomedical systems thinner, lighter, and more flexible. While other components are thoroughly investigated, imperceptible energy storage devices lag behind because the decrease of thickness impairs the area‐specific energy density. Imperceptible supercapacitors with high area‐specific capacitance based on reduced graphene oxide/polyaniline (RGO/PANI) composite electrodes and polyvinyl alcohol (PVA)/H2SO4 gel electrolyte are reported. Two strategies to realize a supercapacitor with a total device thickness of 5 µm—including substrate, electrode, and electrolyte—and an area‐specific capacitance of 36 mF cm−2 simultaneously are implemented. First, the void volume of the RGO/PANI electrodes through mechanical compression is reduced, which decreases the thickness by 83% while retaining 89% of the capacitance. Second, the PVA‐to‐H2SO4 mass ratio is decreased to 1:4.5, which improves the ion conductivity by 5000% compared to the commonly used PVA/H2SO4 gel. Both advantages enable a 2 µm‐thick gel electrolyte for planar interdigital supercapacitors. The impressive electromechanical stability of the imperceptible supercapacitors by wrinkling the substrate to produce folds with radii of 6 µm or less is demonstrated. The supercapacitors will be meaningful energy storage modules for future self‐powered imperceptible electronics.

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“…The emergence of wearable technologies capable of multimodal, clinical-grade monitoring of physiological health increases the demand for sensors, systems, and data analytics approaches that enable reliable, continuous operation during natural daily activities. By comparison to traditional devices that loosely couple to the wrist, skin-mounted technologies offer vastly superior measurement capabilities due to their persistent, intimate interfaces to the body (1)(2)(3)(4)(5). This mode of operation can support a range of clinically standard diagnostic assessments, such as those based on electrocardiography (2,(6)(7)(8)(9)(10)(11), photoplethysmography (10)(11)(12)(13)(14)(15), arterial tonometry (16)(17)(18)(19)(20), and others (21)(22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33)(34).…”

Section: Introductionmentioning

confidence: 99%

“…4 Department of Mechanical Engineering, Northwestern University, Evanston, IL 60208, USA. 5 Feinberg School of Medicine, Northwestern University, Chicago, IL 60611, USA. 6 Department of Biomedical Engineering, Northwestern University, Evanston, IL 60208, USA.…”

Section: Introductionmentioning

confidence: 99%

Differential cardiopulmonary monitoring system for artifact-canceled physiological tracking of athletes, workers, and COVID-19 patients

Jeong

Lee

et al. 2021

Sci. Adv.

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Soft, skin-integrated electronic sensors can provide continuous measurements of diverse physiological parameters, with broad relevance to the future of human health care. Motion artifacts can, however, corrupt the recorded signals, particularly those associated with mechanical signatures of cardiopulmonary processes. Design strategies introduced here address this limitation through differential operation of a matched, time-synchronized pair of high-bandwidth accelerometers located on parts of the anatomy that exhibit strong spatial gradients in motion characteristics. When mounted at a location that spans the suprasternal notch and the sternal manubrium, these dual-sensing devices allow measurements of heart rate and sounds, respiratory activities, body temperature, body orientation, and activity level, along with swallowing, coughing, talking, and related processes, without sensitivity to ambient conditions during routine daily activities, vigorous exercises, intense manual labor, and even swimming. Deployments on patients with COVID-19 allow clinical-grade ambulatory monitoring of the key symptoms of the disease even during rehabilitation protocols.

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Nanomesh pressure sensor for monitoring finger manipulation without sensory interference

Cited by 430 publications

References 40 publications

Recent Progress on Flexible Capacitive Pressure Sensors: From Design and Materials to Applications

Recent Progress on Flexible Capacitive Pressure Sensors: From Design and Materials to Applications

Imperceptible Supercapacitors with High Area‐Specific Capacitance

Differential cardiopulmonary monitoring system for artifact-canceled physiological tracking of athletes, workers, and COVID-19 patients

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