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1. Multiscale Characterization of the Influence of the Organic–Inorganic Interface on the Dielectric Breakdown of Nanocomposites

Author

Pieters, Priscilla F, Lainé, Antoine, Li, He, Lu, Yi-Hsien, Singh, Yashpal, Wang, Lin-Wang, Liu, Yi, Xu, Ting, Alivisatos, A Paul, and Salmeron, Miquel

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences, Engineering, Materials Engineering, Nanotechnology, Bioengineering, interfaces, nanocomposites, self-assembled monolayers, dielectric breakdown, nanoparticles, charge retention, Kelvin probe force microscopy, MSD-General, MSD-Nanocomposites, Nanoscience & Nanotechnology
Abstract

Nanoscale engineered materials such as nanocomposites can display or be designed to enhance their material properties through control of the internal interfaces. Here, we unveil the nanoscale origin and important characteristics of the enhanced dielectric breakdown capabilities of gold nanoparticle/polymer nanocomposites. Our multiscale approach spans from the study of a single chemically designed organic/inorganic interface to micrometer-thick films. At the nanoscale, we relate the improved breakdown strength to the interfacial charge retention capability by combining scanning probe measurements and density functional theory calculations. At the meso- and macroscales, our findings highlight the relevance of the nanoparticle concentration and distribution in determining and enhancing the dielectric properties, as well as identifying this as a crucial limiting factor for the achievable sample size.

Published
2022

2. Trap Passivation in Indium-Based Quantum Dots through Surface Fluorination: Mechanism and Applications

Author

Kim, Tae-Gon, Zherebetskyy, Danylo, Bekenstein, Yehonadav, Oh, Myoung Hwan, Wang, Lin-Wang, Jang, Eunjoo, and Alivisatos, A Paul

Subjects
Physical Sciences, Engineering, Nanotechnology, indium phosphide, quantum dots, fluorine, etching, atomic ligand, indium arsenide, Nanoscience & Nanotechnology
Abstract

Treatment of InP colloidal quantum dots (QDs) with hydrofluoric acid (HF) has been an effective method to improve their photoluminescence quantum yield (PLQY) without growing a shell. Previous work has shown that this can occur through the dissolution of the fluorinated phosphorus and subsequent passivation of indium on the reconstructed surface by excess ligands. In this article, we demonstrate that very significant luminescence enhancements occur at lower HF exposure though a different mechanism. At lower exposure to HF, the main role of the fluoride ions is to directly passivate the surface indium dangling bonds in the form of atomic ligands. The PLQY enhancement in this case is accompanied by red shifts of the emission and absorption peaks rather than blue shifts caused by etching as seen at higher exposures. Density functional theory shows that the surface fluorination is thermodynamically preferred and that the observed spectral characteristics might be due to greater exciton delocalization over the outermost surface layer of the InP QDs as well as alteration of the optical oscillator strength by the highly electronegative fluoride layer. Passivation of surface indium with fluorides can be applied to other indium-based QDs. PLQY of InAs QDs could also be increased by an order of magnitude via fluorination. We fabricated fluorinated InAs QD-based electrical devices exhibiting improved switching and higher mobility than those of 1,2-ethanedithiol cross-linked QD devices. The effective surface passivation eliminates persistent photoconductivity usually found in InAs QD-based solid films.

Published
2018

4. PbS Nanoparticles Capped with Tetrathiafulvalene­tetracarboxylate: Utilizing Energy Level Alignment for Efficient Carrier Transport

Author

Scheele, Marcus, Hanifi, David, Zherebetskyy, Danylo, Chourou, Slim T, Axnanda, Stephanus, Rancatore, Benjamin J, Thorkelsson, Kari, Xu, Ting, Liu, Zhi, Wang, Lin-Wang, Liu, Yi, and Alivisatos, A Paul

Subjects
Macromolecular and Materials Chemistry, Engineering, Chemical Sciences, Nanotechnology, Bioengineering, semiconductor nanoparticles, organic semiconductors, hybrid materials, field-effect transistors, Nanoscience & Nanotechnology
Abstract

We fabricate a field-effect transistor by covalently functionalizing PbS nanoparticles with tetrathiafulvalenetetracarboxylate. Following experimental results from cyclic voltammetry and ambient-pressure X-ray photoelectron spectroscopy, we postulate a near-resonant alignment of the PbS 1Sh state and the organic HOMO, which is confirmed by atomistic calculations. Considering the large width of interparticle spacing, we observe an abnormally high field-effect hole mobility, which we attribute to the postulated resonance. In contrast to nanoparticle devices coupled through common short-chained ligands, our system maintains a large degree of macroscopic order as revealed by X-ray scattering. This provides a different approach to the design of hybrid organic-inorganic nanomaterials, circumvents the problem of phase segregation, and holds for versatile ways to design ordered, coupled nanoparticle thin films.

Published
2014

5. PbS nanoparticles capped with tetrathiafulvalenetetracarboxylate: utilizing energy level alignment for efficient carrier transport.

Author

Scheele, Marcus, Hanifi, David, Zherebetskyy, Danylo, Chourou, Slim T, Axnanda, Stephanus, Rancatore, Benjamin J, Thorkelsson, Kari, Xu, Ting, Liu, Zhi, Wang, Lin-Wang, Liu, Yi, and Alivisatos, A Paul

Subjects
semiconductor nanoparticles, organic semiconductors, hybrid materials, field-effect transistors, Nanoscience & Nanotechnology
Abstract

We fabricate a field-effect transistor by covalently functionalizing PbS nanoparticles with tetrathiafulvalenetetracarboxylate. Following experimental results from cyclic voltammetry and ambient-pressure X-ray photoelectron spectroscopy, we postulate a near-resonant alignment of the PbS 1Sh state and the organic HOMO, which is confirmed by atomistic calculations. Considering the large width of interparticle spacing, we observe an abnormally high field-effect hole mobility, which we attribute to the postulated resonance. In contrast to nanoparticle devices coupled through common short-chained ligands, our system maintains a large degree of macroscopic order as revealed by X-ray scattering. This provides a different approach to the design of hybrid organic-inorganic nanomaterials, circumvents the problem of phase segregation, and holds for versatile ways to design ordered, coupled nanoparticle thin films.

Published
2014

6. Quantifying Intracellular Nanoparticle Distributions with Three-Dimensional Super-Resolution Microscopy

Author

Vinit Sheth, Xuxin Chen, Evan M. Mettenbrink, Wen Yang, Meredith A. Jones, Ons M’Saad, Abigail G. Thomas, Rylee S. Newport, Emmy Francek, Lin Wang, Alex N. Frickenstein, Nathan D. Donahue, Alyssa Holden, Nathan F. Mjema, Dixy E. Green, Paul L. DeAngelis, Joerg Bewersdorf, and Stefan Wilhelm

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Published
2023
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9. Boosting the Sensitivity of WSe2 Phototransistor via Janus Interfaces with 2D Perovskite and Ferroelectric Layers

Author

Tong Tong, Yuquan Gan, Weisheng Li, Wei Zhang, Haizeng Song, Hehe Zhang, Kan Liao, Jie Deng, Si Li, Ziyue Xing, Yu Yu, Yudi Tu, Wenhui Wang, Jinlian Chen, Jing Zhou, Xuefen Song, Linghai Zhang, Xiaoyong Wang, Shuchao Qin, Yi Shi, Wei Huang, and Lin Wang

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Published
2022
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10. Self-Powered Seawater Electrolysis Based on a Triboelectric Nanogenerator for Hydrogen Production

Author

Baofeng Zhang, Chuguo Zhang, Ou Yang, Wei Yuan, Yuebo Liu, Lixia He, Yuexiao Hu, Zhihao Zhao, Linglin Zhou, Jie Wang, and Zhong Lin Wang

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

Water splitting for yielding high-purity hydrogen represents the ultimate choice to reduce carbon dioxide emission owing to the superior energy density and zero-pollution emission after combustion. However, the high electricity consumption and requirement of large quantities of pure water impede its large-scale application. Here, a triboelectric nanogenerator (W-TENG) converting offshore wind energy into electricity is proposed for commercial electric energy saving and cost reduction. By introducing PTFE/POM dielectric pairs with matched HOMO/LUMO band gap energy, a high charge density is achieved to promote the output of W-TENG. With the impedance matching design of transformers with the internal resistance of W-TENG, the output current is further enhanced from 1.42 mA to 54.5 mA with a conversion efficiency of more than 92.0%. Furthermore, benefiting from the high electrocatalytic activity (overpotential = 166 mV and Tafel slope = 181.2 mV dec

Published
2022
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11. Triboelectric Patch Based on Maxwell Displacement Current for Human Energy Harvesting and Eye Movement Monitoring

Author

Jiaqing Zhu, Yuanming Zeng, Yu Luo, Yang Jie, Feifei Lan, Jun Yang, Zhong Lin Wang, and Xia Cao

Subjects
Wearable Electronic Devices, Electric Power Supplies, Eye Movements, General Engineering, Humans, Nanotechnology, General Physics and Astronomy, General Materials Science, Monitoring, Physiologic
Abstract

The forthcoming wearable health care devices garner considerable attention because of their potential for monitoring, treatment, and protection applications. Herein, a self-powered triboelectric patch was developed using polytetrafluoroethylene rubbed with nylon fabric. The triboelectric patch can maintain a stable electrostatic field, due to the excess electrification on the surface of the triboelectric layer. The designed triboelectric nanogenerator (TENG) output watt density can reach about 485 mW/m

Published
2022
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12. Ultrastretchable Organogel/Silicone Fiber-Helical Sensors for Self-Powered Implantable Ligament Strain Monitoring

Author

Feifan Sheng, Bo Zhang, Yihan Zhang, Yanyan Li, Renwei Cheng, Chuanhui Wei, Chuan Ning, Kai Dong, and Zhong Lin Wang

Subjects
Electric Power Supplies, Ligaments, Silicones, General Engineering, Humans, Animals, Nanotechnology, General Physics and Astronomy, General Materials Science, Rabbits, Monitoring, Physiologic
Abstract

Implantable sensors with the abilities of real-time healthcare monitoring and auxiliary training are important for exercise-induced or disease-induced muscle and ligament injuries. However, some of these implantable sensors have some shortcomings, such as requiring an external power supply or poor flexibility and stability. Herein, an organogel/silicone fiber-helical sensor based on a triboelectric nanogenerator (OFS-TENG) is developed for power-free and sutureable implantation ligament strain monitoring. The OFS-TENG with high stability and ultrastretchability is composed of an organogel fiber and a silicone fiber intertwined with a double helix structure. The organogel fiber possesses the merits of rapid preparation (15 s), good transparency (95%), high stretchability (600%), and favorable stability (over 6 months). The OFS-TENG is successfully implanted on the patellar ligament of the rabbit knee for the real-time monitoring of knee ligament stretch and muscle stress, which is expected to provide a solution for real-time diagnosis of muscle and ligament injuries. The prepared self-powered OFS-TENG can monitor data on human muscles and ligaments in real-time.

Published
2022
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14. Multiscale Characterization of the Influence of the Organic–Inorganic Interface on the Dielectric Breakdown of Nanocomposites

Author

Priscilla F. Pieters, Antoine Lainé, He Li, Yi-Hsien Lu, Yashpal Singh, Lin-Wang Wang, Yi Liu, Ting Xu, A. Paul Alivisatos, and Miquel Salmeron

Subjects
dielectric breakdown, self-assembled monolayers, General Engineering, General Physics and Astronomy, Bioengineering, MSD-Nanocomposites, Kelvin probe force microscopy, interfaces, MSD-General, nanocomposites, Nanotechnology, nanoparticles, General Materials Science, Nanoscience & Nanotechnology, charge retention
Abstract

Nanoscale engineered materials such as nanocomposites can display or be designed to enhance their material properties through control of the internal interfaces. Here, we unveil the nanoscale origin and important characteristics of the enhanced dielectric breakdown capabilities of gold nanoparticle/polymer nanocomposites. Our multiscale approach spans from the study of a single chemically designed organic/inorganic interface to micrometer-thick films. At the nanoscale, we relate the improved breakdown strength to the interfacial charge retention capability by combining scanning probe measurements and density functional theory calculations. At the meso- and macroscales, our findings highlight the relevance of the nanoparticle concentration and distribution in determining and enhancing the dielectric properties, as well as identifying this as a crucial limiting factor for the achievable sample size.

Published
2022
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15. Gyroscope-Structured Triboelectric Nanogenerator for Harvesting Multidirectional Ocean Wave Energy

Author

Qi Gao, Yuhong Xu, Xin Yu, Zhaoxu Jing, Tinghai Cheng, and Zhong Lin Wang

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

Wave motion in the ocean can generate plentiful energy, but it is difficult to harvest wave energy for practical use because of the low frequency and random directional characteristics of wave motion. In this paper, a gyroscope-structured triboelectric nanogenerator (GS-TENG) is proposed for harvesting multidirectional ocean wave energy. Its inner and outer generation units can operate independently in different directions, and they all adopt the friction mode of surface contact. While realizing noninterference multidirectional energy harvesting, the power generation area is increased. In the experiments, under acceleration of 6 m/s

Published
2022
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16. A Dual-Mode Triboelectric Nanogenerator for Wind Energy Harvesting and Self-Powered Wind Speed Monitoring

Author

Lixia He, Chuguo Zhang, Baofeng Zhang, Ou Yang, Wei Yuan, Linglin Zhou, Zhihao Zhao, Zhiyi Wu, Jie Wang, and Zhong Lin Wang

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

The triboelectric nanogenerator shows a broad application potential in wind energy collection and wind speed sensing. However, it is difficult to realize wind energy collection and real-time wind speed monitoring in one simple device without external power support. Here, a high-performance dual-mode triboelectric nanogenerator is proposed to simultaneously collect wind energy efficiently and monitor wind speed in real time, which is composed by an alternating current triboelectric nanogenerator (AC-TENG) and a direct-current triboelectric nanogenerator (DC-TENG). Based on the material optimization, the charge density of the AC-TENG improves by a factor of 1 compared with previous works. Moreover, benefiting from the elastic structure and material optimization to realize a low friction force, the AC-TENG shows an excellent durability and obtains a retention of 87% electric output after 1 200 000 operation cycles. Meanwhile, thanks to the high charge density and low friction force, the energy-harvesting efficiency of the AC-TENG is doubled. In addition, the DC-TENG not only displays an excellent real-time sensing performance but also can provide gale warning. Our finding exhibits a strategy for efficiently collecting wind energy and achieving fully self-powered and real-time wind speed monitoring.

Published
2022
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17. Recent Advances in Triboelectric Nanogenerators: From Technological Progress to Commercial Applications

Author

Dongwhi Choi, Younghoon Lee, Zong-Hong Lin, Sumin Cho, Miso Kim, Chi Kit Ao, Siowling Soh, Changwan Sohn, Chang Kyu Jeong, Jeongwan Lee, Minbaek Lee, Seungah Lee, Jungho Ryu, Parag Parashar, Yujang Cho, Jaewan Ahn, Il-Doo Kim, Feng Jiang, Pooi See Lee, Gaurav Khandelwal, Sang-Jae Kim, Hyun Soo Kim, Hyun-Cheol Song, Minje Kim, Junghyo Nah, Wook Kim, Habtamu Gebeyehu Menge, Yong Tae Park, Wei Xu, Jianhua Hao, Hyosik Park, Ju-Hyuck Lee, Dong-Min Lee, Sang-Woo Kim, Ji Young Park, Haixia Zhang, Yunlong Zi, Ru Guo, Jia Cheng, Ze Yang, Yannan Xie, Sangmin Lee, Jihoon Chung, Il-Kwon Oh, Ji-Seok Kim, Tinghai Cheng, Qi Gao, Gang Cheng, Guangqin Gu, Minseob Shim, Jeehoon Jung, Changwoo Yun, Chi Zhang, Guoxu Liu, Yufeng Chen, Suhan Kim, Xiangyu Chen, Jun Hu, Xiong Pu, Zi Hao Guo, Xudong Wang, Jun Chen, Xiao Xiao, Xing Xie, Mourin Jarin, Hulin Zhang, Ying-Chih Lai, Tianyiyi He, Hakjeong Kim, Inkyu Park, Junseong Ahn, Nghia Dinh Huynh, Ya Yang, Zhong Lin Wang, Jeong Min Baik, and Dukhyun Choi

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Published
2023
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18. Flexible Wood-Based Triboelectric Self-Powered Smart Home System

Author

Xue Shi, Jianjun Luo, Jianzhe Luo, Xunjia Li, Kai Han, Ding Li, Xia Cao, and Zhong Lin Wang

Subjects
Electric Power Supplies, Artificial Intelligence, General Engineering, Humans, General Physics and Astronomy, General Materials Science, Electronics, Wood
Abstract

With the rapid development of the Internet of Things, artificial intelligence, and big data, the smart home has played a critical role in human life and smart cities, where large amounts of distributed sensors should be applied. Here, we report a natural wood-based triboelectric self-powered sensor (WTSS) for building the smart home system. Based on an effective and simple treatment strategy for natural wood, the WTSS shows superior sensitivity, flexibility, stability, and thinness. Owing to the extensive use of wood materials in home construction, the WTSS is integrated with household facilities and applied in three real-time human-machine interfaces, including a smart home control system, a smart password gate control system, and a smart floor monitoring system, with advantages of low cost, easy operation, and eco-friendliness. This work promotes the development of wood-based flexible electronics and shows potential applications in the construction of smart homes and future cities.

Published
2022
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19. Nondestructive Dimension Sorting by Soft Robotic Grippers Integrated with Triboelectric Sensor

Author

Sheng Zhang, Baosen Zhang, Da Zhao, Qi Gao, Zhong Lin Wang, and Tinghai Cheng

Subjects
Silicon, Hand Strength, Elastic Modulus, General Engineering, General Physics and Astronomy, General Materials Science, Equipment Design, Robotics
Abstract

In smart logistics, traditional manual sorting and sorting systems based on rigid manipulators limit the warehousing development and damage the goods. Here, a nondestructive sorting method based on bionic soft fingers is proposed. This method is implemented by the soft robotic gripper (SRG) for grasping of the breakable objects, the triboelectric sensor (TES) for size sorting of the objects, and the signal processing module. In the fabrication of SRG, the silicon rubber is prepared by controlling the material synthesis process, and its Young's modulus is 600.91 kPa, which is comparable to the Young's modulus of skin tissue. Also, the maximum input pressure of SRG is 71.4 kPa. The TES has a linear relationship between pulse number and sliding displacement, and its resolution is 3 mm. It induces pulse signal sequences to quantify the SRG bending state and thus realize the size sorting of objects. Additionally, a nondestructive sorting system based on TES and SRG has been developed for fruit sorting (e.g., apples, oranges), enabling nondestructive grasping and accurate sorting. Its sorting range is 70-120 mm, and the sorting accuracy rate is up to 95%. This work also provides a way for the application of SRG and triboelectric sensors in the sorting field.

Published
2022
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20. Helical Fiber Strain Sensors Based on Triboelectric Nanogenerators for Self-Powered Human Respiratory Monitoring

Author

Chuan Ning, Renwei Cheng, Yang Jiang, Feifan Sheng, Jia Yi, Shen Shen, Yihan Zhang, Xiao Peng, Kai Dong, and Zhong Lin Wang

Subjects
Wearable Electronic Devices, Electric Power Supplies, Respiratory System, General Engineering, Humans, General Physics and Astronomy, General Materials Science, Monitoring, Physiologic
Abstract

Respiration is a major vital sign, which can be used for early illness diagnosis and physiological monitoring. Wearable respiratory sensors present an exciting opportunity to monitor human respiratory behaviors in a real-time, noninvasive, and comfortable way. Among them, fiber-shaped triboelectric nanogenerators (FS-TENGs) are attractive for their comfort and high degree of freedom. However, the single-electrode FS-TENGs cannot respond to their own tensile strains, and the coaxial double-electrode FS-TENGs show low sensitivity to strain due to structural limitations. Here, a type of helical fiber strain sensor (HFSS) is developed, which can respond to tiny tensile strains. In addition, a smart wearable real-time respiratory monitoring system is developed based on the HFSSs, which can measure some key breathing parameters for disease prevention and medical diagnosis. An intelligent alarm can automatically call a preset mobile phone for help in response to respiratory behavior changes. This work provides an effective helical structure for fabricating highly sensitive strain sensors based on FS-TENGs and develops wearable self-powered real-time respiratory monitoring systems.

Published
2022
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22. A Flexible and Ultra-Highly Sensitive Tactile Sensor through a Parallel Circuit by a Magnetic Aligned Conductive Composite

Author

Yang Jiang, Fei Liang, Hua Yang Li, Xin Li, You Jun Fan, Jin Wei Cao, Yi Ming Yin, Ying Wang, Zhong Lin Wang, and Guang Zhu

Subjects
Wearable Electronic Devices, Artificial Intelligence, Electric Conductivity, General Engineering, Humans, General Physics and Astronomy, General Materials Science, Dimethylpolysiloxanes
Abstract

The development of flexible electronic skins with high performance and multifunctional sensing capabilities is of great significance for applications ranging from healthcare monitoring to artificial intelligence. To mimic and surpass the high-gauge-factor sensing properties of human skin, structure design and appropriate material selection of sensors are both essentially required. Here, we present an efficient, low-cost fabrication strategy to construct an ultra-highly sensitive, flexible pressure sensor by embedding the aligned nickel-coated carbon fibers (NICFs) in a polydimethylsiloxane (PDMS) substrate. Our design substantially contributes to ultrahigh sensitivity through the parallel circuit formed by aligned NICFs as well as surface spinosum microstructure molded by sandpaper. As a result, the sensor exhibits excellent sensitivity (15 525 kPasup-1/sup), a fast response time (30 ms), and good stability over 3000 loading-unloading cycles. Furthermore, these superior sensing properties trigger applications in water quality and wave monitoring in conjunction with mechanical flexibility and robustness. As a precedent for adjusting the sensitivities of the sensor, the NICFs/PDMS sensor provides a promising method for multiscenario healthcare monitoring, multiscale pressure spatial distribution, and human-machine interfacing.

Published
2022
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23. Triboelectric Nanogenerator Array as a Probe for In Situ Dynamic Mapping of Interface Charge Transfer at a Liquid-Solid Contacting

Author

Jinyang Zhang, Shiquan Lin, and Zhong Lin Wang

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

Contact between water droplets with hydrophobic surfaces is a common phenomenon at functional interfaces, and it has been extensively studied. However, quantifying the charge transfer between the liquid-solid interfacial contacting, especially for the charge density distribution throughout the movement of liquid droplet on a dielectric surface, remains to be investigated. Here, we developed a pixeled droplet triboelectric nanogenerator (pixeled droplet-TENG) array with high-density electrode array as a probe for measuring the charge transfer at a liquid-solid interface when a water drop moves on the hydrophobic surface. To intuitively observe the charge transfer between the liquid-solid interface, we "imaged" the transferred charges along movement trajectory of a water droplet as it slides along a tilted solid surface at a spatial resolution of 0.4 mm and time sensitivity of 0.02 s. Our study shows that the transferred charges are not uniformly distributed along the path, which is possibly due to the two-step model of electron transfer and ion adsorbed on the solid surface, and thus the formation of an electric double layer will inevitably shield the net surface on the solid surface. Our study presents a probe technology with potential applications in surface chemistry, physics, material science, and cell biology.

Published
2023

24. Piezoelectric Nanogenerator for Highly Sensitive and Synchronous Multi-Stimuli Sensing

Author

Huijing Xiang, Xiaomin Huang, Lixia Yan, Chaojie Lv, Zhong Lin Wang, Cao Xia, Yin Lu, Xueqing Wang, Kaili Wu, Ning Wang, Qinghao Qin, and Jinlong Zheng

Subjects
Materials science, business.industry, General Engineering, Electrical engineering, Nanogenerator, General Physics and Astronomy, Reconfigurability, Piezoelectricity, Elasticity, Highly sensitive, Wearable Electronic Devices, Elastomers, Touch, General Materials Science, business, Mechanical Phenomena
Abstract

Smart sensors are expected to be sustainable, stretchable, biocomfortable, and tactile over time, either in terms of mechanical performance, reconfigurability, or energy supply. Here, a biocompatible piezoelectric electronic skin (PENG) is demonstrated on the base of PZT-SEBS (lead zirconate titanate and styrene ethylene butylene styrene) composite elastomer. The highly elastic (with an elasticity of about 950%) PENG can not only harvest mechanical energy from ambient environment, but also show low toxicity and excellent sensing performance toward multiple external stimuli. The synchronous and independent sensing performance toward motion capture, temperature, voice identification, and especially the dual-dimensional force perception promotes its wide application in physiological, sound restoration, and other intelligent systems.

Published
2021
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25. Highly Efficient, Ultrabroad PdSe2 Phototransistors from Visible to Terahertz Driven by Mutiphysical Mechanism

Author

Liu Xie, Xiaoyue He, Kai Zhang, Wenzhi Yu, Jie Li, Zhuo Dong, Luyi Huang, Lin Wang, Libo Zhang, Yan Zhang, Shenghuang Lin, and Haoran Mu

Subjects
Materials science, Band gap, business.industry, Terahertz radiation, General Engineering, General Physics and Astronomy, Photodetector, Photodetection, Responsivity, Thermal conductivity, Seebeck coefficient, Electric field, Optoelectronics, General Materials Science, business
Abstract

The noble transition metal dichalcogenide palladium diselenide (PdSe2) is an ideal candidate material for broad-spectrum photodetection owing to the large bandgap tunability, high mobility, low thermal conductivity, and large Seebeck coefficient. In this study, self-powered ultrabroadband PdSe2 photodetectors from the visible-infrared to terahertz (THz) region driven by a mutiphysical mechanism are reported. In the visible-infrared region, the photogenerated electron-hole pairs in the PdSe2 body are quickly separated by the built-in electric field at the metal-semiconductor interface and achieve a photoresponsivity of 28 A·W-1 at 405 nm and 0.4 A·W-1 at 1850 nm. In the THz region, PdSe2 photodetectors display a room-temperature responsivity of 20 mA·W-1 at 0.10 THz and 5 mA·W-1 at 0.24 THz based on efficient production of hot carriers in an antenna-assisted structure. Owing to the fast response speed of ∼7.5 μs and low noise equivalent power of ∼900 pW·Hz-1/2, high-resolution transmission THz imaging is demonstrated under an ambient environment at room temperature. Our research validates the great potential of PdSe2 for broadband photodetection and provides a possibility for future optoelectronic applications.

Published
2021
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26. Nonintrusion Monitoring of Droplet Motion State via Liquid–Solid Contact Electrification

Author

Zheng Wang, Ren Tao, Xiaosong Zhang, Zhong Lin Wang, Zixuan Song, Wei Long, and Tinghai Cheng

Subjects
Signal processing, Work (thermodynamics), Materials science, business.industry, Microfluidics, General Engineering, Nanogenerator, General Physics and Astronomy, Linearity, Physics::Fluid Dynamics, Physics::Atomic and Molecular Clusters, Optoelectronics, General Materials Science, business, Contact electrification, Pulse-width modulation, Triboelectric effect
Abstract

Droplet motion state monitoring is important in microfluidic applications, such as biomedicine, drug delivery, and metal ion extraction. Here, a nonintrusion monitoring method of droplet motion state via liquid-solid contact electrification is proposed, and a triboelectric droplet motion state sensor (TDMSS) is fabricated. Droplet counting and droplet size monitoring can be realized by signal processing and information extracting of the voltage pulse. The experimental results show that the number of droplets increases linearly with the increase of liquid flow, and the linearity is 0.9854. Moreover, TDMSS can stably monitor the number of droplets in different motion states. In addition, the output pulse width is sensitive to droplet size, and the droplet length ranges from 3 to 13.5 mm. More importantly, TDMSS can realize the function of droplet counting and size monitoring of a conductive liquid and accurate droplet counting under different inclination angles and motion states. This work not only provides a nonintrusion method for droplet motion state monitoring but also makes a solid step for microfluidic sensing technology based on a triboelectric nanogenerator.

Published
2021
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27. A Hydrophobic Self-Repairing Power Textile for Effective Water Droplet Energy Harvesting

Author

Xiao Peng, Renwei Cheng, Yihan Zhang, Yang Jiang, Di Liu, Feifan Sheng, Zhong Lin Wang, Kai Dong, Chuan Ning, and Cuiying Ye

Subjects
chemistry.chemical_classification, Materials science, Energy conversion efficiency, General Engineering, General Physics and Astronomy, Polymer, Perfluorodecyltrichlorosilane, Contact angle, chemistry.chemical_compound, Chemical engineering, chemistry, Air permeability specific surface, General Materials Science, Glass transition, Energy harvesting, Triboelectric effect
Abstract

Triboelectric nanogenerators (TENGs) are useful for harvesting clean and widely distributed water droplet energy with high efficiency. However, the commonly used polymer films in TENGs for water droplet energy harvesting have the disadvantages of poor breathability, poor skin affinity, and irreparable hydrophobicity, which greatly hinder their wearable uses. Here, we report an all-fabric TENG (F-TENG), which not only has good air permeability and hydrophobic self-repairing properties but also shows effective energy conversion efficiency. The hydrophobic surface composed of SiO2 nanoparticles and poly(vinylidenefluoride-co-hexafluoropropylene)/perfluorodecyltrichlorosilane (PVDF-HFP/FDTS) exhibits a static contact angle of 157° and displays excellent acid and alkali resistance. Because of its low glass transition temperature, PVDF-HFP can facilitate the movement of FDTS molecules to the surface layer under heating conditions, realizing hydrophobic self-repairing performance. Furthermore, with the optimized compositions and structure, the water droplet F-TENG shows 7-fold enhancement of output voltage compared with the conventional single-electrode mode TENG, and a total energy conversion efficiency of 2.9% is achieved. Therefore, the proposed F-TENG can be used in multifunctional wearable devices for raindrop energy harvesting.

Published
2021
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28. Triboelectric Nanogenerator for Ocean Wave Graded Energy Harvesting and Condition Monitoring

Author

Jianping Li, Jianming Wen, Xu Yuhong, Tinghai Cheng, Xiaohui Lu, Yanfei Yang, Zhong Lin Wang, and Yang Weixiong

Subjects
Electricity generation, Transmission (telecommunications), Acoustics, Wind wave, General Engineering, Nanogenerator, General Physics and Astronomy, Environmental science, Condition monitoring, General Materials Science, Energy harvesting, Energy (signal processing), Triboelectric effect
Abstract

Using triboelectric nanogenerators (TENGs) to harvest blue energy in the ocean is advanced technology at present. In wave environments, the wave magnitude is constantly changing, so designing a TENG that can adjust the energy harvesting ability is necessary. Herein, a graded energy harvesting triboelectric nanogenerator (GEH-TENG) is fabricated, in which double generation units can operate in different transmission states to adapt to wave changes. Under small waves, the GEH-TENG is in the primary transmission state. Once waves are large enough, it enters the secondary transmission state, realizing graded energy harvesting to enhance power generation performance. Experiments show that when the input frequency is 1.0 Hz and the amplitude is 120 mm, the GEH-TENG can generate 0.7 mJ of energy in a single operation cycle, which is 2.3 times of it without grading. Moreover, it can be placed on the shore to monitor ocean wave conditions. An idea of graded energy harvesting is proposed in this study, and the proposal provides useful guidance for practical applications of TENGs in ocean wave condition monitoring.

Published
2021
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29. Flexible Seaweed-Like Triboelectric Nanogenerator as a Wave Energy Harvester Powering Marine Internet of Things

Author

Yan Wang, Hao Wang, Tiancong Zhao, Liu Xiangyu, Zhong Lin Wang, Yawei Wang, Wang He, Steven L. Zhang, and Minyi Xu

Subjects
Battery (electricity), Power station, Computer science, business.industry, General Engineering, Nanogenerator, Electrical engineering, General Physics and Astronomy, Power (physics), General Materials Science, Electricity, Underwater, business, Internet of Things, Triboelectric effect
Abstract

The marine internet of things (MIoT), an increasingly important foundation for ocean development and protection, consists of a variety of marine distributed sensors under water. These sensors of the MIoT have always been highly dependent on batteries. To realize in situ power supply, a flexible seaweed-like triboelectric nanogenerator (S-TENG) capable of harvesting wave energy is proposed in this study. The flexible structure, designed with inspiration from the seaweed structure, processes extensive marine application scenarios. The bending and recovering of the S-TENG structure under wave excitations are converted to electricity. As the output performance increases with the number of parallel connected S-TENG units, an S-TENG system with multiple units could serve for floating buoys, coastal power stations, and even submerged devices. Through the demonstration experiments performed in this study, the flexible, low-cost S-TENG could become an effective approach to achieve a battery independent MIoT.

Published
2021
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30. All-Weather Droplet-Based Triboelectric Nanogenerator for Wave Energy Harvesting

Author

Zhiyi Wu, Wei Yuan, Zhihao Zhao, Chuguo Zhang, Jie Wang, Zhong Lin Wang, and Xuelian Wei

Subjects
Work (thermodynamics), Computer science, General Engineering, Nanogenerator, General Physics and Astronomy, Mechanical engineering, law.invention, Capacitor, Reliability (semiconductor), law, Marine energy, General Materials Science, Contact electrification, Energy harvesting, Triboelectric effect
Abstract

The liquid-solid triboelectric nanogenerator (LS-TENG) has been demonstrated to harvest energy efficiently through the contact electrification effect between liquid and solid triboelectric materials, which can avoid the wear issue in solid-solid TENG. However, the droplet-based LS-TENG reveals the problems that it generally works with the continuous falling droplets or needs to be fully packaged, which greatly limit its practical application. Here, a droplet-based triboelectric nanogenerator (DB-TENG) with a simple open structure is designed to effectively solve these problems. The nonpackaged DB-TENG can work stably under extreme conditions with high humidity or high concentrations of salt, acid, or alkali solutions, showing the DB-TENGs can be flexibly utilized in all types of working environments with better reliability and lower maintenance costs. It is of great significance that the integrated DB-TENG network array can realize the all-weather ocean energy harvesting. Furthermore, under the simulated ocean wave, a scaled-up DB-TENG with considerable output performance can charge capacitors and drive electrical devices. Overall, the DB-TENG shows many advantages: simple open structure, all-weather working ability, timely supplement of water loss, no tight packaging, wear resistance, suitable for extreme working environments. This work provides a convenient and feasible way toward all-weather wave energy harvesting in real marine environments.

Published
2021
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31. Spatially Controlled Preparation of Layered Metallic–Semiconducting Metal Chalcogenide Heterostructures

Author

Hai Li, Lin Wang, Chuang Shen, Zhimin Luo, Wei Huang, Xiaoshan Wang, Xiao Huang, Qian Chen, Qiang Wang, Jinyan Zhang, Qingsong Song, Chao Zhu, Zhiwei Wang, Zheng Liu, and Jie Dai

Subjects
Materials science, business.industry, Chalcogenide, General Engineering, General Physics and Astronomy, Heterojunction, Epitaxy, Light scattering, Photothermal conversion, Metal, chemistry.chemical_compound, chemistry, visual_art, visual_art.visual_art_medium, Optoelectronics, General Materials Science, Crystallite, business, Deposition (law)
Abstract

Spatially controlled preparation of heterostructures composed of layered materials is important in achieving interesting properties. Although vapor-phased deposition methods can prepare vertical and lateral heterostructures, liquid-phased methods, which can enable scalable production and further solution processes, have shown limited controllability. Herein, we demonstrate by using wet chemical methods that metallic Sn0.5Mo0.5S2 nanosheets can be deposited epitaxially on the edges of semiconducting SnS2 nanoplates to form SnS2/Sn0.5Mo0.5S2 lateral heterostructures or coated on both the edges and basal surfaces of SnS2 to give SnS2@Sn0.5Mo0.5S2 core@shell heterostructures. They also showed good light-to-heat conversion ability due to the metallic property of Sn0.5Mo0.5S2. In particular, the core@shell heterostructure showed a higher photothermal conversion efficiency than the lateral counterpart, largely due to its randomly oriented and polycrystalline Sn0.5Mo0.5S2 layers with larger interfacing area for multiple internal light scattering.

Published
2021
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32. Real-Time and Online Lubricating Oil Condition Monitoring Enabled by Triboelectric Nanogenerator

Author

Yuan Liu, Zhong Lin Wang, Yijun Shi, Roland Larsson, Di Wang, Fan Zhang, Jinshan Pan, Baodong Chen, and Jun Zhao

Subjects
lubricating oils, Materials science, condition monitoring, General Physics and Astronomy, TENG, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, Adsorption, General Materials Science, Lubricant, Contact electrification, Process engineering, Triboelectric effect, business.industry, triboelectric nanogenerator, General Engineering, Nanogenerator, Condition monitoring, Quartz crystal microbalance, Dissipation, 021001 nanoscience & nanotechnology, 0104 chemical sciences, 0210 nano-technology, business, smart machines
Abstract

An intelligent monitoring lubricant is essential for the development of smart machines because unexpected and fatal failures of critical dynamic components in the machines happen every day, threatening the life and health of humans. Inspired by the triboelectric nanogenerators (TENGs) work on water, we present a feasible way to prepare a self-powered triboelectric sensor for real-time monitoring of lubricating oils via the contact electrification process of oil–solid contact (O–S TENG). Typical intruding contaminants in pure base oils can be successfully monitored. The O–S TENG has very good sensitivity, which even can respectively detect at least 1 mg mL–1 debris and 0.01 wt % water contaminants. Furthermore, the real-time monitoring of formulated engine lubricating oil in a real engine oil tank is achieved. Our results show that electron transfer is possible from an oil to solid surface during contact electrification. The electrical output characteristic depends on the screen effect from such as wear debris, deposited carbons, and age-induced organic molecules in oils. Previous work only qualitatively identified that the output ability of liquid can be improved by leaving less liquid adsorbed on the TENG surface, but the adsorption mass and adsorption speed of liquid and its consequences for the output performance were not studied. We quantitatively study the internal relationship between output ability and adsorbing behavior of lubricating oils by quartz crystal microbalance with dissipation (QCM-D) for liquid–solid contact interfaces. This study provides a real-time, online, self-powered strategy for intelligent diagnosis of lubricating oils.

Published
2021
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33. Effect of Photo-Excitation on Contact Electrification at Liquid–Solid Interface

Author

Xinglin Tao, Yuxiang Shi, Xiangyu Chen, Zhong Lin Wang, Shuyao Li, Shiquan Lin, and Jinhui Nie

Subjects
Materials science, business.industry, General Engineering, Nanogenerator, General Physics and Astronomy, Charge density, 02 engineering and technology, Electron, 010402 general chemistry, 021001 nanoscience & nanotechnology, medicine.disease_cause, 01 natural sciences, 0104 chemical sciences, Ion, Excited state, medicine, Optoelectronics, General Materials Science, 0210 nano-technology, Contact electrification, business, Ultraviolet, Triboelectric effect
Abstract

Liquid-solid triboelectric nanogenerator (L-S TENG) is one of the major techniques to collect energy from tiny liquids, while the saturated charge density at the L-S interface is the key element to decide its performance. Here, we found that the saturated charge density of L-S contact electrification (CE) can be further increased under the illumination of an ultraviolet (UV) light. The fluorine-containing polymers and SiO2 are chosen as the electrification materials and with and without UV illumination on the L-S TENG. A series of experiments have been done to rule out the possible influences of anion generation, chemical change of solid surface, ionization of water, and so on. Therefore, we proposed that electrons belonging to water molecules can be excited to high energy states under UV illumination, which then transfer to solid surface and captured by the solid surface. Finally, a photoexcited electron transfer model is proposed to explain the enhancement of CE under the UV illumination. This work not only helps to further understand CE at L-S interface, but also offers an approach to further enhance the performance of L-S TENG, which can promote the TENG applications in the field of microfluidic systems, liquid energy harvesting, and droplet sensory.

Published
2021
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34. High-Electrification Performance and Mechanism of a Water–Solid Mode Triboelectric Nanogenerator

Author

Yahua He, Xiaolin Wang, Zhong Lin Wang, Khay Wai See, Jing You, Jiajia Shao, and Frank F. Yun

Subjects
Computer science, General Engineering, Nanogenerator, General Physics and Astronomy, Mechanical engineering, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Series and parallel circuits, 01 natural sciences, Electrical phenomena, 0104 chemical sciences, law.invention, Capacitor, law, Equivalent circuit, General Materials Science, Resistor, 0210 nano-technology, Energy harvesting, Triboelectric effect
Abstract

With the advantages of superior wear resistance, mechanical durability, and stability, the liquid-solid mode triboelectric nanogenerator (TENG) has been attracting much attention in the field of energy harvesting and self-powered sensors. However, most reports are primarily observational, and there still lacks a universal model of this kind of TENG. Here, an equivalent circuit model and corresponding governing equations of a water-solid mode TENG are developed, which could easily be extended to other types of liquid-solid mode TENGs. Based on the first-order lumped circuit theory, the full equivalent circuit model of water-solid mode TENG is modeled as a series connection of two capacitors and a water resistor. Accordingly, its output characteristics and critical influences are examined, to investigate the relevant physical mechanism behind them. Afterward, a three-dimensional water-solid TENG array constructed from many single-wire TENGs is fabricated, which can not only harvest tiny amounts of energy from any movement of water, but also can verify our theoretical predictions. The fundamentals of the water-solid mode TENG presented in this work could contribute to solving the problem of electrical phenomena on a liquid-solid interface, and may establish a sound basis for a thorough understanding of the liquid-solid mode TENG.

Published
2021
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35. Recycling of High-Value-Added Aramid Nanofibers from Waste Aramid Resources via a Feasible and Cost-Effective Approach

Author

Meiyun Zhang, Xueyao Ding, Bin Yang, Weiwei Li, and Lin Wang

Subjects
Materials science, Manufacturing process, General Engineering, General Physics and Astronomy, Environmental pollution, 02 engineering and technology, Advanced materials, 010402 general chemistry, 021001 nanoscience & nanotechnology, Pulp and paper industry, 01 natural sciences, 0104 chemical sciences, Aramid, Nanofiber, Ultimate tensile strength, General Materials Science, 0210 nano-technology
Abstract

High-performance aramid fibers are extensively applied in the civil and military fields. A great deal of waste aramid resources originating from the manufacturing process, spare parts, or end of life cycle are wrongly disposed (i.e., landfill, smash, fibrillation), causing a waste of valuable resources as well as severe environmental pollution. Although aramid nanofibers (ANFs) have recently been recently reported as one of the most promising building blocks due to their excellent properties, they suffer from an extremely high production expenditure, thereby greatly hindering their scale-up application. Herein, in this paper, from a resources-saving and cost-reductional perspective, we present a feasible top-down approach to recycle high value-added ANFs with an affordable cost from various waste aramid resources. The results indicate that although the reclaimed ANFs have a molecular weight reduction of 8.1% compared with the recycled aramid fibers, they still exhibit a molecular weight of 43.0 kg·mol-1 that represents the highest value compared to other methods. It is noteworthy that the fabrication cost of ANFs is significantly reduced (∼7 times) due to the reclamation of waste aramid fibers instead of the expensive virgin aramid fibers. The obtained ANFs show impressive tensile strength (149.2 MPa) and toughness (10.43 MJ·m-3), excellent thermal stabilities (Td of 542 °C), and a high specific surface area (65.2 m2·g-1), which endows them to be promising candidates for constructing advanced materials. Compared to the aramid pulp obtained by the traditional recycling method, ANFs show significant advantages in dimensional homogeneity, aspect ratio, dispersibility, film-forming property, and especially the excellent properties of the ANF film. In addition, the scale-up preparation of ANFs from the recycled waste aramid fibers is carried out, demonstrating it is highly economically viable. Therefore, this work provides a highly feasible and cost-effective recycle system to reclaim the waste aramid resources together with significantly reducing the preparation cost of ANFs.

Published
2021
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36. Molding Broadband Dispersion in Twisted Trilayer Hyperbolic Polaritonic Surfaces

Author

Chunqi Zheng, Guangwei Hu, Xingsi Liu, Xianghong Kong, Lin Wang, and Cheng-Wei Qiu

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

Recent advancement in twisted layered metasurfaces can be employed to control the nanoscale flow of light, including the exotic hyperbolic-to-elliptic topological transitions in twisted bilayers (tBL). Such topological transitions can only occur to limited frequency ranges, restricted by the intrinsic in-plane dispersion of individual hyperbolic surfaces. Here, we report that, by controlling interlayer evanescent coupling in twisted polaritonic trilayers, moldable topological transitions of light can be achieved in broadband. We reveal that the required minimum open angle of the individual hyperbolic polaritonic surface for open-to-close topological transitions can be significantly lowered compared to that of the twisted bilayer counterpart. This increases the degree of freedom to enhance and control near-field light-matter interactions and energy management. As an example, we demonstrate a knob to manipulate near-field radiative heat transfer (NFRHT). By rotating the relative angles of trilayers, exotic and tunable thermal conductance can be achieved. Our findings enrich the controllability of light at the nanoscale in broadband, bringing twisted optical materials one step closer to practical applications.

Published
2022

37. Improved Degradation Efficiency of Levofloxacin by a Self-Powered Electrochemical System with Pulsed Direct-Current

Author

Li Liu, Wei Yuan, Zhenfeng Bian, Hexing Li, Zhong Lin Wang, Jie Wang, Di Liu, Linglin Zhou, and Shengyang Chen

Subjects
Passivation, Stator, General Physics and Astronomy, Levofloxacin, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, Superposition principle, Electric Power Supplies, Electricity, law, Nanotechnology, General Materials Science, Electrodes, Triboelectric effect, Mechanical energy, business.industry, Direct current, General Engineering, Nanogenerator, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Electrode, Optoelectronics, 0210 nano-technology, business
Abstract

With the excellent structural design, rotary triboelectric nanogenerator (R-TENG) is suitable for harvesting mechanical energy such as wind energy and water energy to build a self-powered electrochemical system for environmental science. The electrochemical performance has been greatly improved by using the pulsed direct-current (PDC) output of a TENG; however, a full-wave PDC (FW-PDC) is hardly realized in R-TENG devices due to existence of phase superposition. Here, a R-TENG with FW-PDC output is reported to perform a self-powered electro-Fenton system for enhancing the removal efficiency of levofloxacin (OFL). By adjusting the rotation center angle ratio between each rotator and stator unit, the phase superposition of R-TENG caused by multiple parallel electrodes can be effectively eliminated, thus achieving the desired FW-PDC output. Because of the reduced electrode passivation effect, the removal efficiency of OFL is improved by 30% under equal electric charges through using the designed R-TENG with FW-PDC output compared to traditional R-TENG. This study provides a promising methodology to improve the performance of self-powered electrochemical process for treating environment pollutions.

Published
2021
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38. Power Backpack for Energy Harvesting and Reduced Load Impact

Author

Zhaozheng Wang, Jiahao Qiu, Ze Yang, Yang Yiyong, Zhiwei Li, Jia Cheng, Xiao Xuan, Fan Liu, Zhong Lin Wang, Linhong Ji, Yinbo Li, and Lu Yijia

Subjects
Computer science, General Engineering, General Physics and Astronomy, Wearable computer, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Automotive engineering, 0104 chemical sciences, Power (physics), Backpack, Motion, Shock absorber, Electric Power Supplies, Electricity generation, Electricity, Humans, Nanotechnology, General Materials Science, Electronics, 0210 nano-technology, Energy harvesting, Triboelectric effect
Abstract

Long-distance walking with heavy loads is often needed when going hiking or for field rescue, which is prone to cumulative fatigue. There is also a great need for labor-saving and biomechanical energy harvesting in daily life for extended security and communication needs. Here, we report a load-suspended backpack for harvesting the wasted energy of human motion based on a triboelectric nanogenerator (TENG). Two elastomers are incorporated into the backpack to decouple the synchronous movement of the load and the human body, which results in little or no extra accelerative force. With such a design, through theoretical analysis and field experiments, the backpack can realize a reduction of 28.75 % in the vertical oscillation of the load and 21.08 % in the vertical force on the wearer, respectively. Meanwhile, the mechanical-to-electric energy conversion efficiency is modeled and calculated to be 14.02 % under normal walking conditions. The designed backpack has the merits of labor-saving and shock absorption as well as electricity generation, which has the promising potential to be a power source for small-scale wearable and portable electronics, GPS systems, and other self-powered health care sensors.

Published
2021
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39. Electron Transfer as a Liquid Droplet Contacting a Polymer Surface

Author

Aurelia Chi Wang, Jiajia Shao, Fei Zhan, Xiangyu Chen, Shiquan Lin, Zhong Lin Wang, and Liang Xu

Subjects
Work (thermodynamics), Materials science, General Engineering, Nanogenerator, General Physics and Astronomy, Charge density, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, symbols.namesake, Electron transfer, Chemical physics, Ionization, symbols, General Materials Science, van der Waals force, 0210 nano-technology, Contact electrification, Triboelectric effect
Abstract

It has been demonstrated that substantial electric power can be produced by a liquid-based triboelectric nanogenerator (TENG). However, the mechanisms regarding the electrification between a liquid and a solid surface remain to be extensively investigated. Here, the working mechanism of a droplet-TENG was proposed based on the study of its dynamic saturation process. Moreover, the charge-transfer mechanism at the liquid-solid interface was verified as the hybrid effects of electron transfer and ion adsorption by a simple but valid method. Thus, we proposed a model for the charge distribution at the liquid-solid interface, named Wang's hybrid layer, which involves the electron transfer, the ionization reaction, and the van der Waals force. Our work not only proves that TENG is a probe for investigating charge transfer at interface of all phases, such as solid-solid and liquid-solid, but also may have great significance to water energy harvesting and may revolutionize the traditional understanding of the liquid-solid interface used in many fields such as electrochemistry, catalysis, colloidal science, and even cell biology.

Published
2020
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40. Triboelectric Nanogenerator Powered Electrowetting-on-Dielectric Actuator for Concealed Aquatic Microbots

Author

Dongyue Jiang, Guijun Chen, Minyi Xu, Zeng Fan, Yongchen Song, Zhong Lin Wang, and Hongchen Wang

Subjects
business.industry, General Engineering, Nanogenerator, General Physics and Astronomy, 02 engineering and technology, Dielectric, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Electrowetting, Environmental science, General Materials Science, Aerospace engineering, 0210 nano-technology, business, Actuator, Triboelectric effect
Abstract

Aquatic microbots have drawn great research interest due to the demands in aquatic environmental monitoring, inspection, and confined space exploration. Current actuation methods heavily rely on mechanical motion powered by large-amplitude and high-frequency sources, which limit the applications with portability and concealment requirements. Herein we propose a triboelectric nanogenerator (TENG)-enabled electrowetting-on-dielectric (EWOD) actuator (TENG-EWA) for aquatic microbots. The transferred tribo-charges of a disc TENG alternatively modify the surface energy of the EWOD actuator, yielding a capillary wave propagation. The reaction force of the capillary wave actuates the microbot on the water surface. The characteristics of the TENG induced capillary wave are analyzed experimentally and modeled theoretically. An optical transparent microbot (weight of 0.07 g, body length of 1 cm) was actuated forward at a maximum locomotion velocity of 1 cm/s. Diverse locomotion functions are demonstrated: with a load of 3 times to the robot net weight, in seawater, at a silicone-oil/deionized water interface. Besides, the locomotion of the microbot was demonstrated by a wind-driven TENG, and a good concealment performance was achieved under infrared camera and decibel meter. The proposed aquatic TENG-Bot not only shows the potential of converting environmental energy into actuation force for microbots but also reveals advantages in optical, sonic, and infrared concealment.

Published
2020
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41. High-Throughput and Self-Powered Electroporation System for Drug Delivery Assisted by Microfoam Electrode

Author

Linlin Li, Zhirong Liu, Mengqi Wu, Zhong Lin Wang, Zhou Li, Tao Jiang, Deli Xiang, Zhuo Wang, Yuanyuan Cheng, Huanhuan Liu, and Xi Liang

Subjects
Materials science, Polymers, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, Gene delivery, 010402 general chemistry, 01 natural sciences, medicine, Pyrroles, General Materials Science, Electrodes, Cell damage, Triboelectric effect, Electroporation, General Engineering, Nanogenerator, 021001 nanoscience & nanotechnology, medicine.disease, 0104 chemical sciences, Pharmaceutical Preparations, Drug delivery, Electrode, 0210 nano-technology, Voltage
Abstract

Electroporation is an effective approach for drug and gene delivery, but it is still limited by its low-throughput and severe cell damage. Herein, with a self-powered triboelectric nanogenerator as the power source, we demonstrated a high-throughput electroporation system based on the design of biocompatible and flexible polypyrrole microfoam as the electrode within the flow channel. In particular, to lower the imposed voltage, one-dimensional (1D) Ag nanowires were modified on the microfoam electrode to build up a locally enhanced electric field and reduce cell damage. The self-powered electroporation system realized a successful delivery of small and large biomolecules into different cell lines with efficiency up to 86% and cell viability over 88%. The handle throughput achieved as high as 105 cells min-1 on continuously flowed cells. The high-throughput and self-powered electroporation system is expected to have potential applications in the fields of high-throughput drug and gene delivery for in vitro isolated cells.

Published
2020
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42. Sustainable and Biodegradable Wood Sponge Piezoelectric Nanogenerator for Sensing and Energy Harvesting Applications

Author

Francis W. M. R. Schwarze, Hengyu Guo, Guido Panzarasa, Marco R. Binelli, Jianguo Sun, Zhong Lin Wang, Changsheng Wu, Ingo Burgert, Javier Ribera, and Kunkun Tu

Subjects
Materials science, General Engineering, Nanogenerator, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Lead zirconate titanate, 01 natural sciences, Piezoelectricity, Pressure sensor, 0104 chemical sciences, chemistry.chemical_compound, chemistry, General Materials Science, Electronics, 0210 nano-technology, Energy source, Energy harvesting, Mechanical energy
Abstract

Developing low-cost and biodegradable piezoelectric nanogenerators is of great importance for a variety of applications, from harvesting low-grade mechanical energy to wearable sensors. Many of the most widely used piezoelectric materials, including lead zirconate titanate (PZT), suffer from serious drawbacks such as complicated synthesis, poor mechanical properties (e.g., brittleness), and toxic composition, limiting their development for biomedical applications and posing environmental problems for their disposal. Here, we report a low-cost, biodegradable, biocompatible, and highly compressible piezoelectric nanogenerator based on a wood sponge obtained with a simple delignification process. Thanks to the enhanced compressibility of the wood sponge, our wood nanogenerator (15 × 15 × 14 mm3, longitudinal × radial × tangential) can generate an output voltage of up to 0.69 V, 85 times higher than that generated by native (untreated) wood, and it shows stable performance under repeated cyclic compression (≥600 cycles). Our approach suggests the importance of increased compressibility of bulk materials for improving their piezoelectric output. We demonstrate the versatility of our nanogenerator by showing its application both as a wearable movement monitoring system (made with a single wood sponge) and as a large-scale prototype with increased output (made with 30 wood sponges) able to power simple electronic devices (a LED light, a LCD screen). Moreover, we demonstrate the biodegradability of our wood sponge piezoelectric nanogenerator by studying its decomposition with cellulose-degrading fungi. Our results showcase the potential application of a wood sponge as a sustainable energy source, as a wearable device for monitoring human motions, and its contribution to environmental sustainability by electronic waste reduction.

Published
2020
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43. Highly Compressible, Thermally Stable, Light-Weight, and Robust Aramid Nanofibers/Ti3AlC2 MXene Composite Aerogel for Sensitive Pressure Sensor

Author

Lin Wang, Jiaojun Tan, Xueyao Ding, Meiyun Zhang, and Bin Yang

Subjects
Materials science, Composite number, General Engineering, General Physics and Astronomy, Nanotechnology, Aerogel, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Pressure sensor, 0104 chemical sciences, Aramid, Nanofiber, General Materials Science, Thermal stability, 0210 nano-technology, Porosity, Electrical conductor
Abstract

Various wearable aerogel sensors are emerging for their light weight, fairly wide sensing range, and sensitive sensing ability. Aramid nanofibers (ANFs) as a kind of burgeoning building blocks realize multifunctional applications in diversified fields for their innate extinguished mechanical property and thermal stability. Limited by their high insulating property, in this work ANFs were designed to integrate with a 2D emerging MXene sheet with a distinct conductive property. Herein, we report an MXene/ANFs composite aerogel through a feasible controllable vacuum filtration followed by a freeze-drying process. Benefiting from the inerratic 3D hierarchical and "mortar-brick" porous structure with an ultralow density of 25 mg/cm3, MXene/ANFs aerogels are proved to possess high compressible resilience and appealing sensing performance up to 1000 times. Importantly, verified by a series of simulation experiments, the MXene/ANFs aerogel sensor shows a wide detection range (2.0-80.0% compression strain), sensitive sensing property (128 kPa-1), and ultralow detection limit (100 Pa), which still play a flexible role in detecting human light movement and even vigorous sports after undergoing ultrahigh devastating pressures (∼623 kPa). In addition, the MXene/ANFs aerogel sensor can withstand a harsh high temperature of 200 °C and shows excellent flame resistance. The MXene/ANFs aerogel with excellent integrated property, especially the highly sensitive sensing property and excellent thermal stability, presents great potential for a human behavior monitoring sensor and sensing under certain extreme conditions.

Published
2020
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44. Effects of Surface Functional Groups on Electron Transfer at Liquid–Solid Interfacial Contact Electrification

Author

Shiquan Lin, Jianjun Luo, Mingli Zheng, and Zhong Lin Wang

Subjects
Materials science, General Engineering, General Physics and Astronomy, Thermionic emission, 02 engineering and technology, Electron, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Ion, chemistry.chemical_compound, Electron transfer, chemistry, Chemical physics, Electron affinity, Functional group, General Materials Science, Charge carrier, 0210 nano-technology, Contact electrification
Abstract

Contact electrification (CE) at interfaces is sensitive to the functional groups on the solid surface, but its mechanism is poorly understood, especially for the liquid-solid cases. A core controversy is the identity of the charge carriers (electrons or/and ions) in the CE between liquids and solids. Here, the CE between SiO2 surfaces with different functional groups and different liquids, including DI water and organic solutions, is systematically studied, and the contribution of electron transfer is distinguished from that of ion transfer according to the charge decay behavior at surfaces at specific temperature, because electron release follows the thermionic emission theory. It is revealed that electron transfer plays an important role in the CE between liquids and functional group modified SiO2. Moreover, the electron transfer between the DI water and the SiO2 is found highly related to the electron affinity of the functional groups on the SiO2 surfaces, while the electron transfer between organic solutions and the SiO2 is independent of the functional groups, due to the limited ability of organic solutions to donate or gain electrons. An energy band model for the electron transfer between liquids and solids is further proposed, in which the effects of functional groups are considered. The discoveries in this work support the "two-step" model about the formation of an electric double-layer (Wang model), in which the electron transfer occurs first when the liquids contact the solids for the very first time.

Published
2020
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45. Versatile Triboiontronic Transistor via Proton Conductor

Author

Zhong Lin Wang, Jinran Yu, Jia Sun, Huai Zhang, Qijun Sun, Xixi Yang, Jing Han, Chuankun Jia, Youhui Chen, and Mei Ding

Subjects
Materials science, business.industry, Transistor, General Engineering, Electronic skin, General Physics and Astronomy, 02 engineering and technology, Dielectric, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Capacitance, Noise (electronics), 0104 chemical sciences, law.invention, law, Optoelectronics, General Materials Science, 0210 nano-technology, business, Electrical conductor, Triboelectric effect, Proton conductor
Abstract

Iontronics are effective in modulating electrical properties through the electric double layers (EDLs) assisted with ionic migration/arrangement, which are highly promising for unconventional electronics, ionic sensory devices, and flexible interactive interface. Proton conductors with the smallest and most abundant protons (H+) can realize a faster migration/polarization under electric field to form the EDL with higher capacitance. Here, a versatile triboiontronic MoS2 transistor via proton conductor by sophisticated combination of triboelectric modulation and protons migration has been demonstrated. This device utilizes triboelectric potential originated from mechanical displacement to modulate the electrical properties of transistors via protons migration/accumulation. It shows superior electrical properties, including high current on/off ratio over 106, low cutoff current (∼0.04 pA), and steep switching properties (89 μm/dec). Pioneering noise tests are conducted to the tribotronic devices to exclude the possible noise interference introduced by mechanical displacement. The versatile triboiontronic MoS2 transistor via proton conductor has been utilized for mechanical behavior derived logic devices and an artificial sensory neuron system. This work represents the reliable and effective triboelectric potential modulation on electronic transportation through protonic dielectrics, which is highly desired for theoretical study of tribotronic gating, active mechanosensation, self-powered electronic skin, artificial intelligence, etc.

Published
2020
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46. In-Plane Ferroelectric Tin Monosulfide and Its Application in a Ferroelectric Analog Synaptic Device

Author

Wei Yu, Hwa Seob Choi, In-Hyeok Park, Kian Ping Loh, Chenliang Su, Teng Ma, Lin Wang, Ki Chang Kwon, Yishu Zhang, Ziyu Zhu, Bingbing Tian, and Xiaojie Wang

Subjects
Materials science, business.industry, General Engineering, General Physics and Astronomy, Conductance, Linearity, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Ferroelectricity, 0104 chemical sciences, Semiconductor, Neuromorphic engineering, chemistry, Synaptic device, Optoelectronics, General Materials Science, Charge carrier, 0210 nano-technology, business, Tin
Abstract

Two-dimensional ferroelectrics is attractive for synaptic device applications because of its low power consumption and amenability to high-density device integration. Here, we demonstrate that tin monosulfide (SnS) films less than 6 nm thick show optimum performance as a semiconductor channel in an in-plane ferroelectric analogue synaptic device, whereas thicker films have a much poorer ferroelectric response due to screening effects by a higher concentration of charge carriers. The SnS ferroelectric device exhibits synaptic behaviors with highly stable room-temperature operation, high linearity in potentiation/depression, long retention, and low cycle-to-cycle/device-to-device variations. The simulated device based on ferroelectric SnS achieves ∼92.1% pattern recognition accuracy in an artificial neural network simulation. By switching the ferroelectric domains partially, multilevel conductance states and the conductance ratio can be obtained, achieving high pattern recognition accuracy.

Published
2020
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47. Continuous and Scalable Manufacture of Hybridized Nano-Micro Triboelectric Yarns for Energy Harvesting and Signal Sensing

Author

Ronghui Wu, Shen Shen, Mengjuan Zhou, Jun Wang, Tingting Wang, Likun Yang, Zhong Lin Wang, Yifan Zhang, Hao Gong, Liyun Ma, Aniruddha Patil, Shuihong Zhu, Kai Dong, and Wenxi Guo

Subjects
Fabrication, Materials science, Textile, Movement, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Signal, Wearable Electronic Devices, Nano, Humans, General Materials Science, Electrodes, Triboelectric effect, business.industry, Textiles, General Engineering, Yarn, 021001 nanoscience & nanotechnology, Electrospinning, 0104 chemical sciences, visual_art, visual_art.visual_art_medium, Optoelectronics, Electronics, 0210 nano-technology, business, Energy harvesting
Abstract

Textile-based triboelectric nanogenerators (TENG) that can effectively harvest biomechanical energy and sense multifunctional posture and movement have a wide range of applications in next-generation wearable and portable electronic devices. Hence, bulk production of fine yarns with high triboelectric output through a continuous manufacturing process is an urgent task. Here, an ultralight single-electrode triboelectric yarn (SETY) with helical hybridized nano-micro core-shell fiber bundles is fabricated by a facile and continuous electrospinning technology. The obtained SETY device exhibits ultralightness (0.33 mg cm-1), extra softness, and smaller size (350.66 μm in diameter) compared to those fabricated by conventional fabrication techniques. Based on such a textile-based TENG, high energy-harvesting performance (40.8 V, 0.705 μA cm-2, and 9.513 nC cm-2) was achieved by applying a 2.5 Hz mechanical drive of 5 N. Importantly, the triboelectric yarns can identify textile materials according to their different electron affinity energies. In addition, the triboelectric yarns are compatible with traditional textile technology and can be woven into a high-density plain fabric for harvesting biomechanical energy and are also competent for monitoring tiny signals from humans or insects.

Published
2020
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48. Smart Mushroom-Inspired Imprintable and Lightly Detachable (MILD) Microneedle Patterns for Effective COVID-19 Vaccination and Decentralized Information Storage

Author

Qilin Li, Rengui Xu, Huiling Fan, Jiarong Xu, Yunruo Xu, Peng Cao, Yan Zhang, Tao Liang, Yang Zhang, Wei Chen, Zheng Wang, Lin Wang, and Xiaoyuan Chen

Subjects
COVID-19 Vaccines, SARS-CoV-2, Vaccination, General Engineering, General Physics and Astronomy, Humans, COVID-19, Information Storage and Retrieval, General Materials Science, Antibodies, Viral, Pandemics
Abstract

The key to controlling the spread of the coronavirus disease 2019 (COVID-19) and reducing mortality is highly dependent on the safe and effective use of vaccines for the general population. Current COVID-19 vaccination practices (intramuscular injection of solution-based vaccines) are limited by heavy reliance on medical professionals, poor compliance, and laborious vaccination recording procedures, resulting in a waste of health resources and low vaccination coverage

Published
2022

49. An Ultrasound-Induced Self-Clearance Hydrogel for Male Reversible Contraception

Author

Zi-Qi Wang, Zhong-Qing Liu, Chang-Hao Zhao, Kuo Zhang, Zhi-Jian Kang, Tian-Rui Qu, Fan-Shu Zeng, Peng-Yu Guo, Zhi-Chao Tong, Chang-Lin Wang, Ke-Liang Wang, Hong-Lei Wang, Yin-Sheng Xu, Wan-Hui Wang, Mao-lin Chu, Lu Wang, Zeng-Ying Qiao, Hao Wang, and Wanhai Xu

Subjects
Male, Contraception, Pregnancy, Semen, General Engineering, General Physics and Astronomy, Humans, General Materials Science, Female, Hydrogels, Reactive Oxygen Species, Ultrasonography
Abstract

Nearly half of pregnancies worldwide are unintended mainly due to failure of contraception, resulting in negative effects on women's health. Male contraception techniques, primarily condoms and vasectomy, play a crucial role in birth control, but cannot be both highly effective and reversible at the same time. Herein, an ultrasound (US)-induced self-clearance hydrogel capable of real-time monitoring is utilized foriin situ/iinjection into the vas deferens, enabling effective contraception and noninvasive recanalization whenever needed. The hydrogel is composed of (i) sodium alginate (SA) conjugated with reactive oxygen species (ROS)-cleavable thioketal (SA-tK), (ii) titanium dioxide (TiOsub2/sub), which can generate a specific level of ROS after US treatment, and (iii) calcium chloride (CaClsub2/sub), which triggers the formation of the hydrogel. For contraception, the above mixture agents are one-time injected into the vas deferens, which can transform from liquid to hydrogel within 160 s, thereby significantly physically blocking the vas deferens and inhibiting movability of sperm. When fertility is needed, a noninvasive remedial ultrasound can make TiOsub2/subgenerate ROS, which cleaves SA-tK to destroy the network of the hydrogel. Owing to the recanalization, the refertility rate is restored to 100%. Meanwhile, diagnostic ultrasound (D-US, 22 MHz) can monitor the occlusion and recanalization process in real-time. In summary, the proposed hydrogel contraception can be a reliable, safe, and reversible male contraceptive strategy that addresses an unmet need for men to control their fertility.

Published
2022

50. Monitoring the Degree of Comfort of Shoes In-Motion Using Triboelectric Pressure Sensors with an Ultrawide Detection Range

Author

Peng Yang, Yuxiang Shi, Shuyao Li, Xinglin Tao, Zhaoqi Liu, Xingling Wang, Zhong Lin Wang, and Xiangyu Chen

Subjects
Motion, Electric Power Supplies, General Engineering, General Physics and Astronomy, Humans, Nanotechnology, General Materials Science, Electrodes, Shoes
Abstract

Shoes play an important role in sports and human daily life. Here, an in-shoe sensor pad (ISSP) attached to the vamp lining is based on a triboelectric nanogenerator (TENG) for monitoring the real-time stress distribution on the top side of a foot. Each sensor unit on this ISSP is an air-capsule TENG (AC-TENG) consisting of activated carbon/polyurethane (AC/PU) and microsphere array electrodes. The detection range of each AC-TENG reaches 7.27 MPa, which is enough for monitoring the pressure change during different sports. This multifunctional ISSP can realize many typical functions of conventional smart shoes, including step counting and human-machine interaction. Moreover, it can also reveal special information, including the fitness of shoes, the stress concentration on toes, and the in-motion comfort degree. The signal processing and data transmission modules in the system have a hybrid power supply with wireless power transfer, while the real-time information about feet can be observed on a cell phone. Hence, this ISSP provides a potential approach to study the feet motion and comfort degree of shoes in long-term operations, which can guide both athlete training and the customized design of shoes.

Published
2022

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