Skin-Inspired Highly Sensitive Tactile Sensors with Ultrahigh Resolution over a Broad Sensing Range

Zhao, Xinhua; Lai, Qin‐Teng; Guo, Wentao; Liang, Zhiwen; Tang, Zhenhua; Tang, Xin‐Gui; Roy, Vellaisamy A. L.; Sun, Qijun

doi:10.1021/acsami.3c04526

Cited by 17 publications

(6 citation statements)

References 49 publications

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“…It is noteworthy that upon reaching a certain absorption duration, the plotted curves transition toward leveling off into a linear segment. This asymptotic behavior corresponds to the attainment of balance or the exhaustion liquid water absorption capacity of the fabrics, thereby signifying the end of the absorption process . Moreover, in Figure c, a detailed examination of the absorption rates against varying cellulose fiber mass ratios reveals intriguing patterns.…”

Section: Resultsmentioning

confidence: 89%

Comfortable, Anisotropic-Elastic, and Multilayered Fibrous Bandages with Enhanced Directional Tensile Performance

Zhang,

Zhai,

Zhen

et al. 2024

ACS Appl. Polym. Mater.

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Elastic fabric bandages exhibit great potential in covering the body contours due to their tensile and comfort performance being well-regulated by their fibrous structure. However, achieving low-coast and facile preparation methods for the fabric bandage with directional tensile performance remains a significant challenge. In this work, a cellulose/polyester composite fabric reinforced by polyolefin−elastomer filament webs (CEL/PET@ POE composite fabrics) was developed by a green and commercialized manufacturing strategy involving a laminating, cross-lapping, and needle-punching process. The resultant composited fabrics possess a multilayered fibrous morphology where fibers are aligned at −45°, 0°(along the longitude direction, i.e., length direction of the fabrics), and +45°. Besides, the POE filaments interweave amid the cellulose/polyester fibrous clusters, resulting in a stable network fibrous structure that offers excellent anisotropic elastic performance and directional extension performance. The fabric displays a breaking strength and elongation in the cross direction that are 2.7 and 0.55 times greater, respectively, compared to those in the machine direction. Moreover, the samples demonstrate brilliant breathability, excellent wearing comfort, and outstanding shape ability. These findings suggest that the prepared CEL/PET@POE composite fabric provides a powerful foundation for a series of potential applications in wearable medical hygiene, such as bandages, electronic textiles, and padding materials.

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Section: Resultsmentioning

confidence: 89%

Comfortable, Anisotropic-Elastic, and Multilayered Fibrous Bandages with Enhanced Directional Tensile Performance

Zhang,

Zhai,

Zhen

et al. 2024

ACS Appl. Polym. Mater.

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“…Aside from high sensitivity, wide pressure detection range is also very important for self-powered tactile sensors. However, it is challenging to reconcile the paradox of great sensitivity with a broad pressure detection range, because a large detection range necessitates superior toughness to prevent mechanical damage, but high sensitivity and low detection limits demand low modulus to respond to minor deformation [ 75 , 76 , 77 ].…”

Section: Main Performance Indicatorsmentioning

confidence: 99%

Recent Advances in Self-Powered Tactile Sensing for Wearable Electronics

Liu,

Li,

Lai

et al. 2024

Materials

Self Cite

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With the arrival of the Internet of Things era, the demand for tactile sensors continues to grow. However, traditional sensors mostly require an external power supply to meet real-time monitoring, which brings many drawbacks such as short service life, environmental pollution, and difficulty in replacement, which greatly limits their practical applications. Therefore, the development of a passive self-power supply of tactile sensors has become a research hotspot in academia and the industry. In this review, the development of self-powered tactile sensors in the past several years is introduced and discussed. First, the sensing principle of self-powered tactile sensors is introduced. After that, the main performance parameters of the tactile sensors are briefly discussed. Finally, the potential application prospects of the tactile sensors are discussed in detail.

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“…However, the saturation of the sensitivity of these sensors due to the lower compressibility of the elastomer at high pressures hinders their further application. Based on this, the irregular microstructures replicated by leaves, petals, sandpaper, , and pollen grains allow for progressive deformation with increasing pressure, leading to high sensitivity over a wide sensing range. Despite the simplicity and cost-effectiveness of preparing such microstructures, the randomly distributed microstructures make the devices less consistent and controllable and harder to tune to adapt to specific applications.…”

Section: Introductionmentioning

confidence: 99%

Two-Stage Micropyramids Enhanced Flexible Piezoresistive Sensor for Health Monitoring and Human–Computer Interaction

Chen,

Qu,

Yao

et al. 2024

ACS Appl. Mater. Interfaces

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High-performance flexible piezoresistive sensors are becoming increasingly essential in various novel applications such as health monitoring, soft robotics, and human−computer interaction. The evolution of the interfacial contact morphology determines the sensing properties of piezoresistive devices. The introduction of microstructures enriches the interfacial contact morphology and effectively boosts the sensitivity; however, the limited compressibility of conventional microstructures leads to rapid saturation of the sensitivity in the low-pressure range, which hinders their application. Herein, we present a flexible piezoresistive sensor featuring a two-stage micropyramid array structure, which effectively enhances the sensitivity while widening the sensing range. Owing to the synergistic enhancement effect resulting from the sequential contact of micropyramids of various heights, the devices demonstrate remarkable performance, including boosting sensitivity (30.8 kPa −1 ) over a wide sensing range (up to 200 kPa), a fast response/recovery time (75/50 ms), and an ultralong durability of 15,000 loading−unloading cycles. As a proof of concept, the sensor is applied to detect human physiological and motion signals, further demonstrating a real-time spatial pressure distribution sensing system and a game control system, showing great potential for applications in health monitoring and human−computer interaction.

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Skin-Inspired Highly Sensitive Tactile Sensors with Ultrahigh Resolution over a Broad Sensing Range

Cited by 17 publications

References 49 publications

Comfortable, Anisotropic-Elastic, and Multilayered Fibrous Bandages with Enhanced Directional Tensile Performance

Comfortable, Anisotropic-Elastic, and Multilayered Fibrous Bandages with Enhanced Directional Tensile Performance

Recent Advances in Self-Powered Tactile Sensing for Wearable Electronics

Two-Stage Micropyramids Enhanced Flexible Piezoresistive Sensor for Health Monitoring and Human–Computer Interaction

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