Your search keyword '"Cheng, Wenlong"' showing total 8 results

1. Hierarchically Oriented Jellyfish‐Like Gold Nanowires Film for Elastronics.

Author

Zhang, Heng, Lin, Fenge, Cheng, Wenlong, Chen, Yi, and Gu, Ning

Subjects

*GOLD films, *NANOWIRES, *ENERGY harvesting, *ENERGY storage, *BIOELECTRONICS, *INDIVIDUALIZED medicine

Abstract

Stretchable electronics (i.e., Elastronics) are essential to the realization of next‐generation wearable bioelectronics for personalized medicine, due to their unique skin‐conformal features ideal for seamless integration with the human body. Significant progress has been made to nanowire‐based elastronics with promising applications ranging from electronic‐skin to advanced energy harvest systems. However, it remains a key challenge to rationally control over the nanowire morphology and configurations to achieve desired multifunctionality. Herein, a stretchable jellyfish‐like gold nanowires film with high conductivity and stretchability is presented by using gold nanostar‐seeded nanowire growth method. They exhibit unique hierarchically oriented structure with gold nanostars as the multi‐branched active sites (top layer) and vertically intertwined nanowires (bottom layer) trailing below the nanostars. Such nanowires film can be stretched up to 200% with a retaining low normalized resistance of 13.8 due to the unique hierarchical structure. Furthermore, the film can be used as stretchable supercapacitor with a 92% capacitance retention and superior durability even after 5000 electrochemical scanning cycles. The method is general, which can be further expanded to other metallic seeds, hence, representing a low‐cost yet efficient strategy for the fabrication of stretchable elastronics and robust energy storage devices for on‐body biosensing and bioelectronics. [ABSTRACT FROM AUTHOR]

Published

2023

2. Free‐Standing 2D Nanoassemblies.

Author

Shi, Qianqian and Cheng, Wenlong

Subjects

*NANOELECTROMECHANICAL systems, *METAL nanoparticles, *MEMBRANE separation, *CHEMICAL detectors, *THIN films, *MAGNETIC nanoparticles

Abstract

Free‐standing 2D nanoassemblies are ultrathin nanomembranes or nanosheets constructed from constituent nanoscale building blocks including metal nanoparticles, quantum dots, and magnetic nanoparticles, typically by a bottom‐up self‐assembly approach. Such free‐standing nanoassemblies are a new class of advanced functional materials that can integrate the unique optoelectronic properties of nanomaterials with thin film mechanics into confined 2D space. This offers attributes such as minimizing substrate effects, facile transfer, and soft devices in comparison to the corresponding substrate‐supported system. This review covers the recent progress in fabrication, characterization, and application of the free‐standing 2D nanoassemblies. To begin with, the attributes of free‐standing 2D nanoassemblies are discussed, followed by the description of fabrication methodologies. Then their novel optical, electronic, mechanical, magnetic, and stimuli responsible properties are covered, and their potential applications in filtration membrane, nanomechanical devices, and chemical sensing are further discussed. Finally, perspectives on the challenges and future opportunities of the free‐standing 2D nanoassemblies are shared. [ABSTRACT FROM AUTHOR]

Published

2020

3. Nanowire‐Based Soft Wearable Human–Machine Interfaces for Future Virtual and Augmented Reality Applications.

Author

Wang, Kaixuan, Yap, Lim Wei, Gong, Shu, Wang, Ren, Wang, Stephen Jia, and Cheng, Wenlong

Subjects

*AUGMENTED reality, *VIRTUAL reality, *HAPTIC devices, *SOFT contact lenses, *PRESSURE sensors, *HUMAN-machine systems

Abstract

A virtual world has now become a reality as augmented reality (AR) and virtual reality (VR) technology become commercially available. Similar to how humans interact with the physical world, AR and VR systems rely on human–machine interface (HMI) sensors to interact with the virtual world. Currently, this is achieved via state of‐the‐art wearable visual and auditory tools that are rigid, bulky, and burdensome, thereby causing discomfort during practical application. To this end, a skin sensory interface has the potential to serve as the next‐generation AR/VR technology because skin‐like wearable sensors have advantages in that they can be ultrathin, ultra‐soft, conformal, and imperceptible, which provides the ultimate comfort and immersive experience for users. In this progress report, nanowire‐based soft wearable HMI sensors including acoustic, strain, pressure sensors, and physiological sensors are reviewed that may be adopted as skin sensory inputs in future AR/VR systems. Further, nanowire‐based soft contact lenses, haptic force, and thermal and vibration actuators are covered as potential means of feedback for future AR/VR systems. Considering the possible effects of the virtual world on human health, skin‐like wearable artery pulses, glucose, and lactate sensors are also described, which may enable imperceptible health monitoring during future AR/VR practices. [ABSTRACT FROM AUTHOR]

Published

2021

4. A Soft Resistive Acoustic Sensor Based on Suspended Standing Nanowire Membranes with Point Crack Design.

Author

Gong, Shu, Yap, Lim Wei, Zhu, Yi, Zhu, Bowen, Wang, Yan, Ling, Yunzhi, Zhao, Yunmeng, An, Tiance, Lu, Yuerui, and Cheng, Wenlong

Subjects

*BASILAR membrane, *AUTOMATIC speech recognition, *ARTIFICIAL membranes, *ACOUSTIC transducers, *COCHLEAR implants, *NANOWIRES, *DETECTORS, *ACOUSTIC emission

Abstract

An artificial basilar membrane (ABM) is an acoustic transducer that mimics the mechanical frequency selectivity of the real basilar membrane, which has the potential to revolutionize current cochlear implant technology. While such ABMs can be potentially realized using piezoelectric, triboelectric, and capacitive transduction methods, it remains notoriously difficult to achieve resistive ABM due to the poor frequency discrimination of resistive‐type materials. Here, a point crack technology on noncracking vertically aligned gold nanowire (V‐AuNW) films is reported, which allows for designing soft acoustic sensors with electric signals in good agreement with vibrometer output—a capability not achieved with corresponding bulk cracking system. The strategy can lead to soft microphones for music recognition comparable to the conventional microphone. Moreover, a soft resistive ABM is demonstrated by integrating eight nanowire‐based sensor strips on a soft trapezoid frame. The wearable ABM exhibits high‐frequency selectivity in the range of 319–1951 Hz and high sensitivity of 0.48–4.26 Pa−1. The simple yet efficient fabrication in conjunction with programmable crack design indicates the promise of the methodology for a wide range of applications in future wearable voice recognition devices, cochlea implants, and human–machine interfaces. [ABSTRACT FROM AUTHOR]

Published

2020

5. Graphene‐Enhanced 3D Chemical Mapping of Biological Specimens at Near‐Atomic Resolution.

Author

Adineh, Vahid R., Zheng, Changxi, Zhang, Qianhui, Marceau, Ross K. W., Liu, Boyin, Chen, Yu, Si, Kae J., Weyland, Matthew, Velkov, Tony, Cheng, Wenlong, Li, Jian, and Fu, Jing

Subjects

*GRAPHENE, *NANOPARTICLES, *THREE-dimensional display systems, *ENCAPSULATION (Catalysis), *ANTIBIOTIC residues

Abstract

Abstract: The direct imaging of individual atoms within the cellular context holds great potential for understanding the fundamental physical and chemical processes in organisms. Here, a novel approach for imaging of electrically insulated biological cells by introducing a graphene encapsulation approach to “disguise” the low‐conductivity barrier is reported. Upon successful coating using a water‐membrane‐based protocol, the electrical properties of the graphene enable voltage pulsing field evaporation for atom probe tomography (APT). Low conductive specimens prepared from both Au nanoparticles and antibiotic‐resistant bacterial cells have been tested. For the first time, a significant graphene‐enhanced APT mass resolving power is also observed confirming the improved compositional accuracy of the 3D data. The introduction of 2D materials encapsulation lays the foundation for a breakthrough direction in specimen preparation from nanomembrane and nanoscale biological architectures for subsequent 3D near‐atomic characterization. [ABSTRACT FROM AUTHOR]

Published

2018

6. Percolating Network of Ultrathin Gold Nanowires and Silver Nanowires toward 'Invisible' Wearable Sensors for Detecting Emotional Expression and Apexcardiogram.

Author

Ho, My Duyen, Ling, Yunzhi, Yap, Lim Wei, Wang, Yan, Dong, Dashen, Zhao, Yunmeng, and Cheng, Wenlong

Subjects

*NANOWIRES, *WEARABLE technology, *CARDIOGRAPHY, *STRAIN sensors, *PERFORMANCE evaluation

Abstract

2 nm thin gold nanowires (AuNWs) have extremely high aspect ratio (≈10 000) and are nanoscale soft building blocks; this is different from conventional silver nanowires (AgNWs), which are more rigid. Here, highly sensitive, stretchable, patchable, and transparent strain sensors are fabricated based on the hybrid films of soft/hard networks. They are mechanically stretchable, optically transparent, and electrically conductive and are fabricated using a simple and cost-effective solution process. The combination of soft and more rigid nanowires enables their use as high-performance strain sensors with the maximum gauge factor (GF) of ≈236 at low strain (<5%), the highest stretchability of up to 70% strain, and the optical transparency is from 58.7% to 66.7% depending on the amount of the AuNW component. The sensors can detect strain as low as 0.05% and are energy efficient to operate at a voltage as low as 0.1 V. These attributes are difficult to achieve with a single component of either AuNWs or AgNWs. The outstanding sensing performance indicates their potential applications as 'invisible' wearable sensors for biometric information collection, as demonstrated in applications for detecting facial expressions, respiration, and apexcardiogram. [ABSTRACT FROM AUTHOR]

Published

2017

7. Black Gold: Broadband, High Absorption of Visible Light for Photochemical Systems.

Author

Ng, Charlene, Yap, Lim Wei, Roberts, Ann, Cheng, Wenlong, and Gómez, Daniel E.

Subjects

*GOLD, *VISIBLE spectra, *PHOTOVOLTAIC power generation, *NANOSTRUCTURED materials, *PHYSICAL vapor deposition, *FINITE element method

Abstract

Here, a black Au surface is presented: a material solely composed of Au that is capable of absorbing more than 92% of the incident light over a spectral region ranging from 300 to 600 nm and that can maintain a high absorbance (above 70%) for wavelengths up to 800 nm. The black Au surface is fabricated by a simple and scalable template-assisted physical vapor deposition technique and possesses the flexibility of adhering to any arbitrary substrate. The high absorbance of Au originates from the close packing of high aspect ratio Au nanotubes possessing a random tapered wall thickness. Fabry-Perot resonances of gap-plasmon modes between the Au nanotubes are also responsible for the strong suppression of reflectance of black Au as demonstrated by finite element method simulations. Furthermore, the ability of this surface to drive photochemical transformations under visible light illumination is demonstrated. Hence, black Au could provide a new paradigm for the use of highly absorbing metal nanostructures to effectively harvest the entire visible spectrum for photorelated applications such as solar fuel production, photodetection, and photovoltaics. [ABSTRACT FROM AUTHOR]

Published

2017

8. Stretchable-Fiber-Confined Wetting Conductive Liquids as Wearable Human Health Monitors.

Author

Guan, Liyun, Nilghaz, Azadeh, Su, Bin, Jiang, Lei, Cheng, Wenlong, and Shen, Wei

Subjects

*WEARABLE technology, *PATIENT monitoring equipment, *FLEXIBLE electronics, *SOLID-liquid interfaces, *FIBERS, *PARKINSON'S disease diagnosis, *PREVENTION of injury

Abstract

Wetting behaviors on stretchable supports are very common in our daily lives, however, received limited attention even they show promising potentials in flexible electronics and other fields. In this study, stretchable wetting behaviors of conductive liquids deposited onto two horizontal rubber fibers are investigated. A firm liquid/solid interaction during the stretching process can contribute to a stable liquid bridge between the fibers even under extremely stretching, showing their proof-to-principle ability to monitor human movement toward early diagnosis of Parkinson's disease or sports injury prevention. [ABSTRACT FROM AUTHOR]

Published

2016