Sustainable Triboelectric Materials for Smart Active Sensing Systems

Wei, Zhiting; Wang, Jinlong; Liu, Yanhua; Yuan, Jinxia; Liu, Tao; Du, Guoli; Zhu, Siqiyuan; Nie, Shuangxi

doi:10.1002/adfm.202208277

Cited by 60 publications

(26 citation statements)

References 212 publications

(276 reference statements)

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“…Other than as supercapacitor, battery, and fuel cell material, cotton-derived materials are also utilized as piezoelectric, triboelectric, photovoltaic materials, etc., which harvest energy. The triboelectric materials are charged electrically and generate energy when electrically contacted via means of rubbing, friction, movement, etc. − These properties make a triboelectric material a potential candidate for wearable and flexible electronics. − Graham et al have fabricated a coin cell triboelectric device by utilizing engineered cotton; this microcrystalline cellulose-triboelectric nanogenerator (MACPF- cc TENG) converts the mechanical energy into electrical energy. The fabricated device shows a high voltage of 600 V with a current density of 50 μA and a high power density of 84.5 W m –2 .…”

Section: Cotton-derived Materials As Other Electronic Devicesmentioning

confidence: 99%

Perspective on Biomass-Based Cotton-Derived Nanocarbon for Multifunctional Energy Storage and Harvesting Applications

Dhiman

Sharma

Ghosh

2023

ACS Appl. Electron. Mater.

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The demand for renewable-energy-based efficient systems is a practical indication to develop sustainable energy nanomaterials for energy storage and conversion to reduce the use of pollution-based nonrenewable energy systems. The use of biomass-derived energy components is a new age for the development of sustainable energy electrode nanomaterials. Among biomass, cotton-based electrodes are more popular, as they are cost-effective and efficient energy materials. Cotton-plant-derived porous or pristine nanocarbons have good textural and morphological properties with high specific surface area, hierarchical porous structure, and large pore volume. The functionalization, addition of active moieties, and easy synthetic routes improve the properties and enhance the performance of various electronic devices. The functionalization of derived materials with a heteroatom perturbs the electrical neutrality of the framework. The incorporation of active sites enhances the surface area and creates defects in the framework. These properties speed up the charge storage and energy conversion reaction for better performance of fabricated devices. This Review gives a detailed understanding and advancements about cotton-derived energy nanomaterial. Also, it gives insight about the key factors affecting the performance of cotton-based electrodes, electrolytes, and other components of energy devices. This Review concludes with the cotton-plant-derived supercapacitor, fuel cell, and battery, with a deep insight into their physicochemical properties. This Review also discusses the role of the active mass of the material used for the different device fabrications, which alters the performance. Further, a deep insight has been provided with a brief discussion of other electronic devices like photovoltaic, triboelectric, and piezoelectric devices based on cotton-derived nanocarbon.

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Section: Cotton-derived Materials As Other Electronic Devicesmentioning

confidence: 99%

Perspective on Biomass-Based Cotton-Derived Nanocarbon for Multifunctional Energy Storage and Harvesting Applications

Dhiman

Sharma

Ghosh

2023

ACS Appl. Electron. Mater.

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“…[4] However, with the booming development of the Internet of Things, [5][6][7] traditional sensors struggle to meet trillions of sensor network requirements owing to maintenance difficulties, high costs, additional energy supplies, and limited lifetime. [8][9][10] Hence, it is highly desirable to develop a low-cost, self-powered vibration sensor that does not require maintenance or an additional energy supply.…”

Section: Introductionmentioning

confidence: 99%

A Highly Sensitive Triboelectric Quasi‐Zero Stiffness Vibration Sensor with Ultrawide Frequency Response

Wang

et al. 2023

Advanced Science

Self Cite

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Sensors based on triboelectric nanogenerators (TENGs) have gained worldwide interest owing to their advantages of low cost and self‐powering. However, the detection of most triboelectric vibration sensors (TVS) is restricted to low frequency, whereas high‐frequency vibration signals are successfully measured in recent studies; their sensitivity still requires improvement. Hence, a highly sensitive vibration sensor based on TENG (HSVS‐TENG) with ultrawide frequency response is presented. This study is the first to introduce a quasi‐zero stiffness structure into the TENG to minimize the driving force by optimizing the magnetic induction intensity and the weight of the moving part. The results show that the HSVS‐TENG can measure vibrations with frequencies ranging from 2.5 to 4000 Hz, with a sensitivity ranging from 0.32 to 134.9 V g−1. Moreover, the sensor exhibits a good linear response versus the applied acceleration, and the linearity ranges from 0.08 to 2.81 V g−1. The self‐powered sensor can monitor the running state and fault type of the key components with a recognition accuracy of 98.9% by leveraging machine‐learning algorithms. The results reach a new height for the ultrawide frequency response and high sensitivity of the TVS and provide an idea for a follow‐up high‐resolution TVS.

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“…[5,18,19] Pulse sensors gained superfluous attention due to their noninvasive nature and practical design. [20,21] TENGs have the potential to address the durability issue in two different ways. One strategy involves using TENGs to produce electrical signals that correspond to health stimuli and use them as self-powered sensors that are not dependent on an external energy source.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Screen‐Printed Single‐Electrode Triboelectric Nanogenerator‐Based Self‐Powered Sensor for Pulse Measurement and Its Characterization

Mathew

Vivekanandan

2023

Energy Tech

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The development of triboelectric nanogenerator technology has many benefits across various fields, particularly in healthcare applications; herein, a concise single‐electrode pulse sensor with a high output performance at a reasonable cost is suggested. The device is made up of a polydimethylsiloxane film with a spacer‐created trench structure stacked on top of a graphene‐coated polyethylene terephthalate film. A comprehensive examination of sensor fabrication together with material and electrical characterization is explained. The entire study is carried out using a graphene–silver composite electrode device, giving an output performance of ≈1.66 and ≈2.9 V for tapping movement in plain and microstructured triboelectric surfaces, respectively; however, for the graphene electrode device, the output obtained is ≈5.5 V. This wearable sensor can successfully extract the typical human wrist pulse, which displays the pressure wave from the radial artery in the range of ≈5 V with the help of an exemplary amplifier circuit and will be suitable to integrate with IoT.

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Sustainable Triboelectric Materials for Smart Active Sensing Systems

Cited by 60 publications

References 212 publications

Perspective on Biomass-Based Cotton-Derived Nanocarbon for Multifunctional Energy Storage and Harvesting Applications

Perspective on Biomass-Based Cotton-Derived Nanocarbon for Multifunctional Energy Storage and Harvesting Applications

A Highly Sensitive Triboelectric Quasi‐Zero Stiffness Vibration Sensor with Ultrawide Frequency Response

Fabrication of Screen‐Printed Single‐Electrode Triboelectric Nanogenerator‐Based Self‐Powered Sensor for Pulse Measurement and Its Characterization

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