Degradable Bioinspired Hypersensitive Strain Sensor with High Mechanical Strength Using a Basalt Fiber as a Reinforced Layer

Sun, Tao; Zhao, Houqi; Zhang, Junqiu; Chen, Yu; Gao, Jiqi; Liu, Linpeng; Niu, Shichao; Han, Zhiwu; Ren, Luquan; Lin, Qiao

doi:10.1021/acsami.2c12479

Cited by 11 publications

(3 citation statements)

References 50 publications

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“…In this study, inspired by the slit sensillum of scorpion, which possesses powerful sensing capability, − we developed a low-cost, large-scale fabrication process for developing wearable plant sensors. Without photolithography, inversion, etching, etc., a 82 μm “scorpion slit” was copied out and then a 120 nm-thick Ag layer was deposited, which exhibited ultrasensitive vibration-sensing capacity and could detect vibrations due to horizontal and vertical growth.…”

Section: Introductionmentioning

confidence: 99%

Wearable Plant Sensors Based on Nanometer-Thick Ag Films on Polyethylene Glycol Terephthalate Substrates for Real-Time Monitoring of Plant Growth

Huang,

Gao

et al. 2023

ACS Appl. Nano Mater.

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The real-time monitoring of growth status, pest and disease prevention, and the extraction of physical and chemical signals of plant are essential for precision and postharvest agriculture. Although multifunctional wearable plant sensors have been used in leaf wetness and growth monitoring, their high fabrication costs and low performance are drawbacks. Herein, a bionic plant sensor with a nanometer-thick Ag film and double Vshaped grooves was fabricated and operated as a scorpion microscale slit receptor to monitor plant growth. The bionic plant sensor showed ultrasensitive vibration detection capability and was fabricated using a very simple and scalable strategy, requiring only 1 h/per and costing $1.3/per. Furthermore, the wireless sensor enabled continuous and real-time growth monitoring of bamboo, which showed a day/night growth tendency consistent with previous intrusive reports. In addition, the wearable plant sensor demonstrated great potential for real-time plant growth detection.

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Section: Introductionmentioning

confidence: 99%

Wearable Plant Sensors Based on Nanometer-Thick Ag Films on Polyethylene Glycol Terephthalate Substrates for Real-Time Monitoring of Plant Growth

Huang,

Gao

et al. 2023

ACS Appl. Nano Mater.

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Section: Introductionmentioning

confidence: 99%

“…Flexible strain sensors are generally composed of two layers: a conductive functional layer sensitive to external strain and a flexible substrate layer for supporting and integrating with the active materials. , One effective strategy to improve the performance of flexible strain sensors within subtle strain variation is to manipulate the functional layers with complex microstructures to generate significant structural and conductivity variations even with small strain changes. , So far, various microstructures have been explored, including micropyramids, porous, microcracks, and biomimetic hierarchical structures . In particular, microcrack structures originating and propagating in brittle thin films along the deformation of underlying flexible supporting layers could significantly enhance the sensitivity of sensors within the subtle strain range by releasing the accommodated stress at the stress concentrated areas. , In this view, Li et al developed a carbon black (CB)/carbon nanotube (CN)-coated paper strain sensor with surface microcracks using the mismatches between the CB/CN coating and substrate materials based on the thermal expansion coefficient and elastic modulus during drying.…”

Section: Introductionmentioning

confidence: 99%

Nanofibrous Matrix Mediated Ultrasensitive Flexible Strain Sensor for Subtle Human Motion Monitoring

Zhang

Peng

et al. 2022

ACS Appl. Electron. Mater.

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Flexible strain sensors have attracted extensive research interest in health monitoring and early diagnosis owing to their superiority in continuous measurement of physiological signals. However, the design of flexible sensors with high sensitivity for subtle strain measurement coupled with biocompatibility, breathability, and eco-friendly properties is still challenging. In this study, a facile and universal approach was developed for the preparation of highly sensitive, biocompatible, and eco-friendly flexible strain sensors in reduced graphene oxide (rGO)/silk composites. The microcrack structures generated in rGO functional layers were achieved by vacuum filtration of GO onto silk nanofibrous matrices followed by a reduction process. The optimized flexible sensor exhibited high sensitivity with a gauge factor (GF) of 436 and 204 at a stretching strain of 8−8.7% and a bending strain of 0.12%, respectively. The sensor also revealed a superfast response of 8.8 ms, excellent durability for over 2000 cycles of bending, and waterproof ability up to 80 °C after 9 cycles. The degradability of the silk substrates enables the recycling of conductive materials, leading to eco-friendly sensor materials. The optimized rGO/silk sensor was able to sensitively and stably detect physiological signals with subtle strain changes (voices, pulse, and airflow), demonstrating great potential for use in flexible strain sensing of human health monitoring and medical diagnostics.

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Revolutionizing digital healthcare networks with wearable strain sensors using sustainable fibers

Zhang,

Xu,

Chen

et al. 2024

SusMat

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Wearable strain sensors have attracted research interest owing to their potential within digital healthcare, offering smarter tracking, efficient diagnostics, and lower costs. Unlike rigid sensors, fiber‐based ones compete with their flexibility, durability, adaptability to body structures as well as eco‐friendliness to environment. Here, the sustainable fiber‐based wearable strain sensors for digital health are reviewed, and material, fabrication, and practical healthcare aspects are explored. Typical strain sensors predicated on various sensing modalities, be it resistive, capacitive, piezoelectric, or triboelectric, are explained and analyzed according to their strengths and weaknesses toward fabrication and applications. The applications in digital healthcare spanning from body area sensing networks, intelligent health management, and medical rehabilitation to multifunctional healthcare systems are also evaluated. Moreover, to create a more complete digital health network, wired and wireless methods of data collection and examples of machine learning are elaborated in detail. Finally, the prevailing challenges and prospective insights into the advancement of novel fibers, enhancement of sensing precision and wearability, and the establishment of seamlessly integrated systems are critically summarized and offered. This endeavor not only encapsulates the present landscape but also lays the foundation for future breakthroughs in fiber‐based wearable strain sensor technology within the domain of digital health.

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Degradable Bioinspired Hypersensitive Strain Sensor with High Mechanical Strength Using a Basalt Fiber as a Reinforced Layer

Cited by 11 publications

References 50 publications

Wearable Plant Sensors Based on Nanometer-Thick Ag Films on Polyethylene Glycol Terephthalate Substrates for Real-Time Monitoring of Plant Growth

Wearable Plant Sensors Based on Nanometer-Thick Ag Films on Polyethylene Glycol Terephthalate Substrates for Real-Time Monitoring of Plant Growth

Nanofibrous Matrix Mediated Ultrasensitive Flexible Strain Sensor for Subtle Human Motion Monitoring

Revolutionizing digital healthcare networks with wearable strain sensors using sustainable fibers

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