2017
DOI: 10.1002/admt.201700284
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Ultrastretchable Strain Sensors Using Carbon Black‐Filled Elastomer Composites and Comparison of Capacitive Versus Resistive Sensors

Abstract: system. [11] Researchers have developed highly stretchable strain sensors made of compliant elastomers and various conductive materials, such as silver nanowire, [12] carbon nanotube (CNT), [13][14][15][16][17][18] carbon grease, [19] graphene, [20] graphite, [21] laser-carbonized polyimide, [22] conductive acrylic elastomer, [10] liquid metal, [23,24] ionic liquid, [25][26][27] and conductive fabric. [28] However, not all of these technologies can be manufactured in large scale at low cost.Here, we propose th… Show more

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Cited by 268 publications
(246 citation statements)
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“…The mechanosensor has a huge range of strain up to 760% (sensitivity 9.2%) compared with only 70% for the “straight” design. This helical strain sensor is highly comparable to other ultrastretchable strain sensors . There was no observable signal degradation after 1000 testing cycles and excellent sensing signal reproducibility fast response times of ≈100 ms.…”
Section: Plant‐inspired Mechanosensorssupporting
confidence: 52%
“…The mechanosensor has a huge range of strain up to 760% (sensitivity 9.2%) compared with only 70% for the “straight” design. This helical strain sensor is highly comparable to other ultrastretchable strain sensors . There was no observable signal degradation after 1000 testing cycles and excellent sensing signal reproducibility fast response times of ≈100 ms.…”
Section: Plant‐inspired Mechanosensorssupporting
confidence: 52%
“…Lastly, our ongoing work is to further improve the sensitivity by optimizing the geometry of the sensors and to understand their mechanical behavior with the aid of analytical and numerical modeling. As demonstrated in many studies for example in Bartlett et al (2016), Nur et al (2018), and Shintake et al (2018b), strain sensors are able to detect bending deformations when placed on the surface of the target object. Therefore, applications of our sensor will also include soft robotic systems that undergo large bending deformations such as grippers, mobile robots, and wearable devices.…”
Section: Resultsmentioning
confidence: 96%
“…While easier to implement, resistive strain sensors show a history‐dependent resistance, making calibration quite challenging. Capacitive sensors are nearly insensitive to the conductivity of the electrodes, and are preferred for larger strains, but require a more complex readout scheme . Capacitive sensors have been integrated for example in electroluminescent skin, and can be made to be very robust …”
Section: Sensing Technologiesmentioning
confidence: 99%