High-Performance Wearable Strain Sensor Based on MXene@Cotton Fabric with Network Structure

Liu, Lu; Wang, Libo; Liu, Xuqing; Yuan, Wenfeng; Yuan, Mengmeng; Xia, Qixun; Hu, Qianku; Zhou, Aiguo

doi:10.3390/nano11040889

Cited by 40 publications

(34 citation statements)

References 43 publications

(28 reference statements)

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“…It was found that the FePS 3 @rGO strain sensor resistance increased linearly with a corresponding gauge factor of 38.7 (R 2 = 0.96) at 40% strain. The obtained gauge factor value was superior to that previously reported for some of the 2D materials and carboncoated textile strain sensors [43][44][45][46] . The repeatability of the FePS 3 @rGO strain sensor was then examined using step and hold strain cycles, and the results are displayed in Supplementary Fig.…”

Section: Remotely Monitoring Physiological Parameterscontrasting

confidence: 73%

Telemedicine platform for health assessment remotely by an integrated nanoarchitectonics FePS3/rGO and Ti3C2-based wearable device

2022

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Due to the emergence of various new infectious (viral/bacteria) diseases, the remote surveillance of infected persons has become most important, especially if hospitals need to isolate infected patients to prevent the spreading of pathogens to health care personnel. Therefore, we develop a remote health monitoring system by integrating a stretchable asymmetric supercapacitor (SASC) as a portable power source with sensors that can monitor the human physical health condition in real-time and remotely. An abnormal body temperature and breathing rate could indicate a person’s sickness/infection status. Here we integrated FePS3@graphene-based strain sensor and SASC into an all-in-one textile system and wrapped it around the abdomen to continuously monitor the breathing cycle of the person. The real body temperature was recorded by integrating the temperature sensor with the SASC. The proposed system recorded physiological parameters in real-time and when monitored remotely could be employed as a screening tool for monitoring pathogen infection status.

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Section: Remotely Monitoring Physiological Parameterscontrasting

confidence: 73%

Telemedicine platform for health assessment remotely by an integrated nanoarchitectonics FePS3/rGO and Ti3C2-based wearable device

2022

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“…fabricated a wearable high‐performance Ti 3 C 2 T x based strain sensor using the dip‐coating method and obtained a gauge factor of 4.11 at 3–15% of applied strain. [ 61 ] Uzun et al. fabricated highly conductive MXene coated cellulose yarns and utilized them as a strain sensor which displayed a gauge factor of 6.02% up to 20% of applied strain.…”

Section: Resultsmentioning

confidence: 99%

MXene/TMD Nanohybrid for the Development of Smart Electronic Textiles Based on Physical Electromechanical Sensors

Adepu

Kamath

Siddhartha

et al. 2021

Adv Materials Inter

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Wearable technologies are becoming gradually prevalent as a personal health system, facilitating unceasing real‐time monitoring of human health on a regular basis and outside the clinical environments. In this perspective, an urgent requirement for extensively sensitive and wearable sensors has increased to examine health during life activities. The fabrication of Ti3C2Tx/SnSe2 nanohybrid E‐textile based multifunctional physical sensors (pressure, strain) on the cotton substrate to monitor an individual's health during daily activities is demonstrated here. The fabricated nanohybrid E‐textile based physical sensors display an extraordinary sensitivity of 14.959 kPa–1 in the applied pressure range of 1.477–3.456 kPa and a gauge factor of 14.108 for 5–25% of applied strain. In addition, these physical sensors show exceptional stability of ≈2500 cycles for a pressure sensor and ≈3000 cycles for a strain sensor which signifies the sturdiness of the sensor. Detailed underlying physics and transduction mechanism are explained by Schottky barrier and tunneling resistance mechanism. Further, an android/iOS/web‐based app is developed to validate wireless integration of the fabricated multifunctional physical sensors for demonstration toward smart shoe and crepe bandage applications.

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“…As a rechargeable secondary battery, LIBs have achieved great commercial success and are widely used in portable electronic products, electric vehicles, and the defense industry, etc., for their advantages of high operating voltage, high energy density, long cycle life, and environmental friendliness [175,230]. However, shortage of lithium resources can be a future problem.…”

Section: New Secondary Batterymentioning

confidence: 99%

From structural ceramics to 2D materials with multi-applications: A review on the development from MAX phases to MXenes

et al. 2021

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MAX phases (Ti3SiC2, Ti3AlC2, V2AlC, Ti4AlN3, etc.) are layered ternary carbides/nitrides, which are generally processed and researched as structure ceramics. Selectively removing A layer from MAX phases, MXenes (Ti3C2, V2C, Mo2C, etc.) with two-dimensional (2D) structure can be prepared. The MXenes are electrically conductive and hydrophilic, which are promising as functional materials in many areas. This article reviews the milestones and the latest progress in the research of MAX phases and MXenes, from the perspective of ceramic science. Especially, this article focuses on the conversion from MAX phases to MXenes. First, we summarize the microstructure, preparation, properties, and applications of MAX phases. Among the various properties, the crack healing properties of MAX phase are highlighted. Thereafter, the critical issues on MXene research, including the preparation process, microstructure, MXene composites, and application of MXenes, are reviewed. Among the various applications, this review focuses on two selected applications: energy storage and electromagnetic interference shielding. Moreover, new research directions and future trends on MAX phases and MXenes are also discussed.

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High-Performance Wearable Strain Sensor Based on MXene@Cotton Fabric with Network Structure

Cited by 40 publications

References 43 publications

Telemedicine platform for health assessment remotely by an integrated nanoarchitectonics FePS3/rGO and Ti3C2-based wearable device

Telemedicine platform for health assessment remotely by an integrated nanoarchitectonics FePS3/rGO and Ti3C2-based wearable device

MXene/TMD Nanohybrid for the Development of Smart Electronic Textiles Based on Physical Electromechanical Sensors

From structural ceramics to 2D materials with multi-applications: A review on the development from MAX phases to MXenes

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