相关参考文献
注意:仅列出部分参考文献,下载原文获取全部文献信息。
Article
Chemistry, Multidisciplinary
Yunzhao Bai et al.
Summary: Advances in fabric strain sensors have led to the development of comfortable-to-wear flexible electronics with excellent permeability and low modulus. However, a challenge that remains unsolved is regulating the sensor response for different applications with varying sensitivity. A simple mechanical strategy of plating functional material on a pre-stretched fabric mat in a certain direction allows for the integration of multiple sensors with different responses or strain-insensitive interconnects on a single substrate. This strategy provides a guideline for on-demand design and fabrication of fabric strain sensors, and its capabilities have been demonstrated in motion monitoring bandages and gesture recognition gloves.
ADVANCED FUNCTIONAL MATERIALS
(2023)
Review
Chemistry, Multidisciplinary
Zhiyuan Gao et al.
Summary: Wearable strain sensors based on electrospun fibers have gained popularity in personalized healthcare due to their excellent mechanical properties, breathability, and light weight. This review provides a systematic introduction to the structure and preparation process of electrospun fibers and the conductive layer. It also discusses the impact of materials and structures on the sensing performance of wearable strain sensors and presents applications in biomonitoring, motion detection, and human-machine interaction. Challenges and future directions for the community of wearable strain sensors based on electrospun fibers are also highlighted.
ADVANCED FUNCTIONAL MATERIALS
(2023)
Review
Engineering, Environmental
Hui Chen et al.
Summary: Flexible and wearable electronics have attracted significant attention in research due to their potential applications in personal healthcare, electronic skins, and human-machine interfaces. Strain sensors, especially those based on two-dimensional carbon-based materials such as graphene, play a crucial role in wearable electronics by efficiently converting external stimuli into electrical signals. This review highlights the need for a comprehensive overview of graphene-based strain sensors that focuses on their attributes, mechanisms, fabrication strategies, and applications in various fields.
CHEMICAL ENGINEERING JOURNAL
(2023)
Article
Materials Science, Multidisciplinary
Penghui Li et al.
Summary: In order to solve the challenges of achieving high sensitivity, wide sensing range, and high stability in flexible sensors, we constructed a micro-crack composite wrinkle structure enhanced fiber strain sensor. The sensor, using SEBS rubber elastomer as the substrate and carbon nanotube film functional materials, has an ultra-wide sensing range of 0-600% and an impact factor of 1.0676 under tension. It maintains good sensing performance after >10,000 tests, has high linearity, a response time of 153 ms, a recovery time of 169 ms, and negligible hysteresis.
DIAMOND AND RELATED MATERIALS
(2023)
Article
Materials Science, Multidisciplinary
Wenke Yang et al.
Summary: By innovatively applying triethylamine, hydrophobic polyimide fibers were uniformly dispersed in a carbon nanotube aqueous dispersion, leading to the development of a pressure sensor with a wide linear sensing range, ultralow detection limit, high sensitivity, and fast response/recovery time.
SCIENCE CHINA-MATERIALS
(2023)
Article
Nanoscience & Nanotechnology
Taoyu Shen et al.
Summary: With the development of flexible electronic devices and IoT technology, flexible strain sensors have great potential. However, achieving wide working range and high response sensitivity is still a challenge. In this study, a flexible CNT@TPU fibrous strain sensor (CTFSS) was developed with a synergistic sensing layer, showing high response sensitivity and wide working range. The CTFSS can be used to monitor small and large-scale human strain, and also has applications in sign language recognition and mechanical palm control.
ADVANCED COMPOSITES AND HYBRID MATERIALS
(2023)
Review
Materials Science, Multidisciplinary
Chuang Zhu et al.
Summary: Fiber materials in wearable electronics offer significant advantages in terms of flexibility, stretchability, and breathability, making them pioneers in the new generation of soft wearables. Extensive research and development have been conducted in the areas of material preparation, fabrication technologies, and diverse wearable applications for fiber-shaped wearable electronics.
ADVANCED FIBER MATERIALS
(2023)
Review
Chemistry, Multidisciplinary
Guorui Chen et al.
Summary: This article summarizes the research progress and potential applications of e-textiles in wearable healthcare systems, including the working mechanisms and clinical application scenarios of textile sensors, therapeutic devices, and protective medical devices. The article also discusses the connection technologies of e-textiles and offers insights into the challenges and future directions in the field.
Review
Nanoscience & Nanotechnology
Zekun Liu et al.
Summary: This paper reviews the latest advances in fiber-based wearable strain sensors, including the methods for preparing conductive fibers, the fabrication and sensing mechanisms of state-of-the-art sensors, and their applications in various fields. It also critically analyzes the challenges and future prospects of fiber-based strain sensors.
NANO-MICRO LETTERS
(2022)
Article
Nanoscience & Nanotechnology
Jingxiang Wang et al.
Summary: A bioinspired strain sensor has been successfully fabricated, using scorpion and spiderweb as bionic prototypes. The sensor shows improvements in sensitivity, stability, and durability, making it highly applicable in various fields.
ACS APPLIED MATERIALS & INTERFACES
(2022)
Article
Materials Science, Ceramics
Bingbing Xu et al.
Summary: This work developed a multifunctional strain sensor with a wide sensing range, high sensitivity, and rapid response speed. The sensor also demonstrated sufficient reliability and stability under repeated strain. It can be applied for detecting various body actions and medical diagnosis, showing potential applications in smart clothing, flexible electronics, and human health monitoring.
CERAMICS INTERNATIONAL
(2022)
Article
Engineering, Environmental
Jian Zhou et al.
Summary: The research team proposed a flexible sensor based on conductive hydrogel, which has high stretchability, sensitivity, and self-adhesiveness. The sensor demonstrates outstanding performance through multiple interpenetrating network architectures and strong interactions, making it applicable in wearable electronics and human motion monitoring.
CHEMICAL ENGINEERING JOURNAL
(2022)
Article
Engineering, Environmental
Dianbo Zhang et al.
Summary: This study develops a high-performance electronic textile with outstanding strain sensing, electromagnetic interference (EMI) shielding, and thermal management performances. The textile is based on a conductive coating of MXene and carbon nanotubes on a thermoplastic polyurethane non-woven fabric. The resulting textile exhibits high sensitivity, wide sensing range, rapid response/recovery time, excellent stability and reliability, as well as superior EMI shielding effectiveness and thermal management performance.
CHEMICAL ENGINEERING JOURNAL
(2022)
Article
Engineering, Electrical & Electronic
Fan Jin et al.
Summary: A high-performance strain sensor based on fabric was developed, featuring high sensitivity, wide strain range, excellent mechanical durability, and stability. This electronic textile can be integrated with other wearable devices to track human motion signals in real-time.
SENSORS AND ACTUATORS A-PHYSICAL
(2022)
Article
Nanoscience & Nanotechnology
Dianbo Zhang et al.
Summary: This study investigates the impedance sensing mechanism of an axon-like ionic conductive hydrogel strain sensor, which exhibits a negative ion concentration-dependent impedance sensing behavior. The hydrogel sensor shows good strain amplitude identifiability, ultralow detection limit, excellent rate independence, and outstanding long-term fatigue resistance. An equivalent circuit model is built to understand the internal sensing mechanism, and the skin-core structure is designed to improve impedance responsivity.
ADVANCED COMPOSITES AND HYBRID MATERIALS
(2022)
Article
Multidisciplinary Sciences
Hongling Sun et al.
Summary: This study successfully developed a superhydrophobic strain sensor with a synergistic carbon nanotubes/reduced graphene oxide dual conductive layer decorated elastic rubber band. The sensor exhibits extremely low detection limit, high sensitivity, wide workable strain range, fast response/recovery, and excellent superhydrophobicity, self-cleaning property, and corrosion-resistance. It provides a universal technique for preparing high-performance strain sensors with great potential applications in the field of next-generation intelligent wearable electronics.
Article
Nanoscience & Nanotechnology
Yuxin He et al.
Summary: In this study, a multifunctional wearable strain/pressure sensor with an ultra-low detection limit was successfully prepared. It exhibited excellent sensing stability and reproductivity under different conditions, making it applicable in real-time human movement monitoring. Moreover, it also displayed great applicability for optical and thermal sensing, providing more functionality for next-generation wearable electronics.
ADVANCED COMPOSITES AND HYBRID MATERIALS
(2022)
Article
Nanoscience & Nanotechnology
Liang Zhao et al.
Summary: This study proposes a flexible multidirectional strain sensor based on a single layer hierarchical aligned micro-/nanowire network. The sensor exhibits high sensitivity, short response/recovery time, good stability, and high selectivity, enabling precise monitoring of subtle movements and posture correction.
ACS APPLIED MATERIALS & INTERFACES
(2022)
Article
Materials Science, Multidisciplinary
Hao Zhang et al.
Summary: With the advancements in IoT and 5G technology, the demand for smart wearable devices is increasing. Flexible strain sensors with high scalability, fast response time, high gauge factor, and stability are being rapidly developed to meet the requirements of electronic skin and smart wearable products. These sensors have diverse applications in detecting physiological and motion signals such as pulse, speech recognition, and joint positions.
JOURNAL OF MATERIALS CHEMISTRY C
(2022)
Review
Materials Science, Multidisciplinary
Xuhua Liu et al.
Summary: With the rapid development of smart products, flexible and stretchable smart wearable electronic devices are considered as pioneers in the new generation of flexible electronic devices. Flexible strain sensors, known for their good flexibility, high sensitivity, high repeatability, and potential in personal healthcare and motion detection, have been widely studied. Unlike traditional bulky sensors, these lightweight portable devices with excellent mechanical and electrical performance meet personalized needs and are becoming more popular.
ADVANCED FIBER MATERIALS
(2022)
Article
Engineering, Multidisciplinary
Wei Zhai et al.
Summary: This study investigated a high-performance flexible and wearable strain sensor, which has the potential for wide applications in health monitoring and disease diagnostics.
COMPOSITES PART B-ENGINEERING
(2021)
Article
Materials Science, Composites
Jia Zeng et al.
Summary: This work presents a fiber-shaped strain sensor made of SEBS/CNT hybrid fibers with high sensitivity, wide sensing range, fast response time, and excellent reliability and stability. The sensor is capable of accurately monitoring both large and subtle human motion in real time, demonstrating its potential application in health monitoring and wearable electronic devices.
COMPOSITES COMMUNICATIONS
(2021)
Review
Chemistry, Multidisciplinary
Yunsheng Fang et al.
Summary: Thermoregulation is crucial for human health, and traditional heating and cooling systems are inefficient. Emerging textiles, due to innovations in materials chemistry and nanotechnology, are more personalized and energy-saving. The advancement in smart thermoregulatory textiles offers insights for sustainable development and personalized comfort.
CHEMICAL SOCIETY REVIEWS
(2021)
Article
Engineering, Multidisciplinary
Bei Li et al.
COMPOSITES PART B-ENGINEERING
(2020)
Article
Chemistry, Multidisciplinary
Chuang Zhu et al.
Article
Nanoscience & Nanotechnology
Chang-Ge Zhou et al.
ACS APPLIED MATERIALS & INTERFACES
(2019)
Article
Chemistry, Multidisciplinary
Jidong Shi et al.
ADVANCED MATERIALS INTERFACES
(2019)
Article
Engineering, Environmental
Jiefeng Gao et al.
CHEMICAL ENGINEERING JOURNAL
(2019)
Review
Chemistry, Physical
Sisi Cao et al.
JOURNAL OF MATERIALS CHEMISTRY A
(2019)
Article
Chemistry, Physical
Xiaoting Li et al.
Article
Chemistry, Multidisciplinary
Li Li et al.
Article
Chemistry, Multidisciplinary
Honglie Song et al.
Article
Chemistry, Multidisciplinary
Yin Cheng et al.
Article
Chemistry, Multidisciplinary
Yichen Cai et al.
ADVANCED MATERIALS
(2017)
Article
Chemistry, Multidisciplinary
Xinqin Liao et al.
ADVANCED FUNCTIONAL MATERIALS
(2016)
Article
Chemistry, Multidisciplinary
Xinming Li et al.
ADVANCED FUNCTIONAL MATERIALS
(2016)
Article
Chemistry, Multidisciplinary
Chunya Wang et al.
ADVANCED MATERIALS
(2016)
Article
Chemistry, Multidisciplinary
Tingting Yang et al.
Article
Chemistry, Multidisciplinary
Shingo Harada et al.
Article
Multidisciplinary Sciences
Daeshik Kang et al.
