Your search keyword '"Shichao Niu"' showing total 8 results

1. Paper-Based Sensor with Bioinspired Macrogrooves for Dual Pressure and Mechanical Strain Signal Detection

Author

Jianhao Li, Zhongwen Yao, Xiancun Meng, Changchao Zhang, Tao Sun, Wenda Song, Haoran Li, Junqiu Zhang, Shichao Niu, Linpeng Liu, Zhiwu Han, and Luquan Ren

Subjects

General Materials Science

Published

2022

2. Degradable Bioinspired Hypersensitive Strain Sensor with High Mechanical Strength Using a Basalt Fiber as a Reinforced Layer

Author

Tao Sun, Houqi Zhao, Junqiu Zhang, Yu Chen, Jiqi Gao, Linpeng Liu, Shichao Niu, Zhiwu Han, Luquan Ren, and Qiao Lin

Subjects

Silicon, Wearable Electronic Devices, Elastomers, Silicates, Textiles, General Materials Science

Abstract

Flexible strain sensors have received extensive attention due to their broad application prospects. However, a majority of present flexible strain sensors may fail to maintain normal sensing performances upon external loads because of their low strength and thus their performances are affected drastically with increasing loads, which severely restricts large-area popularization and application. Scorpions with hypersensitive vibration slit sensilla are coincident with a similar predicament. Herein, it is revealed that scorpions intelligently use risky slits to detect subtle vibrations, and meanwhile, the distinct layered composites of the main body of this organ prevent catastrophic failure of the sensory structure. Furthermore, the extensive use of flexible sensors will generate a mass of electronic waste just as obsoleting silicon-based devices. Considering mechanical properties and environmental issues, a flexible strain sensor based on an elastomer (Ecoflex)-wrapped fabric with the woven structure was designed and fabricated. Note that introducing a "green" basalt fiber (BF) into a degradable elastomer can effectively avoid environmental issues and significantly enhance the mechanical properties of the sensor. As a result, it shows excellent sensitivity (gauge factor (GF) ∼138.10) and high durability (∼40,000 cycles). Moreover, the reduced graphene oxide (RGO)/BF/Ecoflex flexible strain sensor possesses superior mechanical properties (tensile strength ∼20 MPa) and good flexibility. More significantly, the sensor can maintain normal performances under large external tensions, impact loads, and even underwater environments, providing novel design principles for environmentally friendly flexible sensors under extremely harsh environments.

Published

2022

3. Flexible Equivalent Strain Sensor with Ordered Concentric Circular Curved Cracks Inspired by Scorpion

Author

Xiancun Meng, Tao Sun, Linpeng Liu, Changchao Zhang, Houqi Zhao, Dakai Wang, Junqiu Zhang, Shichao Niu, Zhiwu Han, and Luquan Ren

Subjects

General Materials Science

Abstract

Slit sensillum, a unique sensing organ on the scorpion's legs, is composed of several cracks with curved shapes. In fact, it is just its particular morphological distribution and structure that endows the scorpions with ultrasensitive sensing capacity. Here, a scorpion-inspired flexible strain sensor with an ordered concentric circular curved crack array (CCA) was designed and fabricated by using an optimized solvent-induced and template transfer combined method. The morphology of the cracks can be effectively controlled by the heating temperature and the lasting time. Instead of the nonuniform stress distribution induced by disordered cracks, ordered concentric circle curved structures are introduced to generate a uniform stress distribution and larger deformation, which can significantly improve the performance of the strain sensor. Thus, the CCA sensor exhibits ultrahigh sensitivity (GF ∼ 7878.6), excellent stability (over 16 000 cycles), and fast response time (110 ms). Furthermore, the CCA sensor was demonstrated to be feasible for monitoring human motions and detecting noncontact vibration signals, indicating its great potential in human-health monitoring and vibration signal detection applications.

Published

2022

4. A Selective-Response Bioinspired Strain Sensor Using Viscoelastic Material as Middle Layer

Author

Wang Kejun, Shichao Niu, Meng Xiancun, Zhiwu Han, Dakai Wang, Yuqiang Fang, Guoliang Ma, Liu Linpeng, Jingxiang Wang, Tao Sun, Junqiu Zhang, Zhang Changchao, and Luquan Ren

Subjects

Materials science, Noise (signal processing), Acoustics, General Engineering, Slit sensilla, General Physics and Astronomy, Strain rate, Vibration, Signal, Viscoelasticity, Wearable Electronic Devices, Gauge factor, General Materials Science, Sensitivity (control systems)

Abstract

Flexible strain sensors have an irreplaceable role in critical and emerging fields, such as electronic skins, flexible robots, and prosthetics. Although numerous efforts have been made to improve sensor sensitivity to meet specific application scenarios, the signal-to-noise ratio (SNR) is an extremely critical and non-negligible indicator, which takes into account higher sensitivity, meaning that they can also detect the noise signals with high sensitivity. Coincidentally, scorpions with ultrasensitive vibration sensilla also face such a dilemma. Here, it is found that the scorpion ingeniously uses the viscoelastic material in front of its slit sensilla to realize efficient preprocessing of the signal. Its mechanism is that the loss factor of materials changes with frequency, affecting energy storage and transmission. Inspired by this ingenious strategy, a bioinspired strain sensor insensitive to a low strain rate was designed using a two-step template transfer method. As a result, its relative change in resistance reached 110% under the same strain (0.3197%) but with different strain rates (0.1 Hz and ∼20 Hz). The noncontact vibration experiments also show different responses to low-frequency vibration and high-frequency impact. Moreover, it can also be used as a typical flexible strain sensor. Under the tensile state, it has a gauge factor (GF) as high as 4596 upon 0.6% strain, and the response time is 140 ms. Therefore, it is expected that this strain sensor will be used in many important ultraprecision measurement fields, especially when the measured signal is small.

Published

2021

5. Large-Scale Bio-Inspired Flexible Antireflective Film with Scale-Insensitivity Arrays

Author

Delei Liu, Liu Linpeng, Zhiwu Han, Ding Hanliang, Junqiu Zhang, Mu Zhengzhi, Jie Zhao, Ze Wang, Conghao Xu, Luquan Ren, Jian Li, Bo Li, and Shichao Niu

Subjects

Optics and Photonics, Nanostructure, Materials science, Light, Scale (ratio), Creatures, business.industry, Scattering, Equipment Design, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, law.invention, Template, Anti-reflective coating, Flexible display, law, Optoelectronics, General Materials Science, 0210 nano-technology, business, Absorption (electromagnetic radiation)

Abstract

Natural creatures can always provide perfect strategies for excellent antireflection (AR), which is valuable for photovoltaic industry, optical devices, and flexible displays. However, limited by precision, it is still difficult to guarantee the consistency between the artificial structures and the original biological structures. Here, a novel large-scale flexible AR film is inspired by the cicada wings and successfully fabricated with a recycled template. On the one hand, the adjustable structures on porous templates make it possible to optimize the design of AR structure parameters toward the practical demand. On the other hand, it breaks the limitation of the biological organism size, accomplishing the replication of AR nanostructure units in a large scale. Interestingly, even if the film is covered by enlarged dome cone arrays, it still maintains almost perfect AR property, achieving excellent scale-insensitivity AR performance. This work numerically and experimentally investigates its scale-insensitivity AR performance in detail. Compared with subwavelength nanocones, enlarged cones change the original optical behaviors, and the proportion of transmitted light is reduced while scattering and absorption increase. Based on this, these bio-inspired scale-insensitivity AR arrays could be used in flexible displays, photothermic conversion, solar cells, and so on.

Published

2021

6. Broader-Band and Flexible Antireflective Films with the Window-like Structures Inspired by the Backside of Butterfly Wing Scales

Author

Bo Li, Ding Hanliang, Delei Liu, Wang Ze, Luquan Ren, Shichao Niu, Conghao Xu, and Zhiwu Han

Subjects

Materials science, business.industry, Infrared, Photovoltaic system, Window (computing), 02 engineering and technology, Substrate (printing), 010402 general chemistry, 021001 nanoscience & nanotechnology, Solar energy, 01 natural sciences, 0104 chemical sciences, law.invention, Anti-reflective coating, law, Optoelectronics, General Materials Science, 0210 nano-technology, business, Refractive index, Visible spectrum

Abstract

Antireflective performance is critical for most optical devices, such as the efficient solar energy utilization in photovoltaic cells of an aerospace craft and optical displays of scientific precise equipment. Therein, outstanding broad-band antireflection is one of the most crucial properties for antireflection films (ARFs). Unfortunately, it is still a challenging work to realize perfect "broader-band" antireflection because both the low refractive indices materials and time-consuming nanotexturing technologies are required in the fabricating process. Even in this case, a broader-band and flexible ARF with hierarchical structures is successfully developed, which is inspired by butterfly wing scales. First, the butterfly wings surface is treated with acid and stuck on a clean glass. Now, all the scales on the wings will form a strong adhesion with the glass substrate. Then, the wings are removed and the scales are left on the glass slide. Now the backside of scales is facing outward, the backside structures of the scales are coincidentally used as the template. Finally, the structure is replicated and the ARF with a controllable thickness is successfully fabricated by rotating PDMS on the biological template. In this work, the bionic ARFs realize the transmission of nearly 90% and more than 90% in the visible light and infrared region. It enhanced transmission to 13% under standard illumination compared with flat PDMS films of the same thickness. Furthermore, the ARF is flexible enough that it could bend nearly 180° to meet the special antireflection requirements in some extreme conditions. It is expected that this bioinspired AR film could revolutionize the technologies of broader-band antireflective materials and impact numerous applications from glass displays to optoelectronic devices.

Published

2021

7. Flexible Self-Cleaning Broadband Antireflective Film Inspired by the Transparent Cicada Wings

Author

Bo Li, Feng Xiaoming, Jiao Zhibin, Zhiwu Han, Shichao Niu, Ze Wang, Luquan Ren, Junqiu Zhang, and Jie Zhao

Subjects

Materials science, Fabrication, Nanostructure, Surface Properties, Optical communication, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, Hemiptera, Biomimetic Materials, law, Broadband, Animals, Wings, Animal, General Materials Science, business.industry, Replica, Silicon Dioxide, 021001 nanoscience & nanotechnology, Nanostructures, 0104 chemical sciences, Anti-reflective coating, Flexible display, Optoelectronics, 0210 nano-technology, business, Hydrophobic and Hydrophilic Interactions, Template method pattern

Abstract

Cicada wings, covered with arranged nanostructures, were widely studied owing to their high transparency and low reflection. However, limited by technologies, their exquisite surface structures and multifunctional features were not inherited and applied by most artificial materials adequately. Here, the excellent optical properties of the cicada wing were investigated in detail experimentally and theoretically. Besides, a flexible self-cleaning broadband antireflective film inspired by the cicada wing has been successfully fabricated by a well-designed biological template method and sol-gel process. The cicada wing ( Megapomponia intermedia) was selected as the original template directly, and a SiO2 negative replica was obtained by a sol-gel process. Then, chemical corrosion was used to remove the original template, retaining the pure negative replica. Subsequently, the polymethyl methacrylate (PMMA) positive replica could be rebuilt after another sol-gel process. Compared with a flat PMMA film, the average reflectivity of the structured PMMA film over the visible region was reduced from 10 to 2%. Besides, the bio-inspired film with a thickness of 0.18 mm exhibited satisfactory comprehensive performances with low reflectance (≤2%) in most of the visible region, as well as superhydrophobic property and perfect flexibility. Our results offered a quick and simple method to rebuild the nanostructured functional materials, promoting the practical applications of the bionic nanostructured materials. Meanwhile, the modified biomimetic fabrication method provides a solution for rebuilding exquisite biological materials and designing multifunctional surfaces. Moreover, the multifunctional antireflective film with wider universality will exhibit an enormous potential application value in optical communications, photoelectric devices, flexible display screens, and antidazzle glasses.

Published

2019

8. Bioinspired Omnidirectional Self-Stable Reflectors with Multiscale Hierarchical Structures

Author

Luquan Ren, Junqiu Zhang, Ze Wang, Mu Zhengzhi, Shichao Niu, Feng Xiaoming, Zhiwu Han, and Bo Li

Subjects

Coupling, Materials science, biology, business.industry, Reflector (antenna), 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, biology.organism_classification, 01 natural sciences, Optical stability, 0104 chemical sciences, Highly sensitive, Optics, Papilio palinurus, General Materials Science, 0210 nano-technology, Omnidirectional antenna, business, Structural coloration

Abstract

Structured surfaces, demonstrating various wondrous physicochemical performances, are ubiquitous phenomena in nature. Butterfly wings with impressive structural colors are an interesting example for multiscale hierarchical structures (MHSs). However, most natural structural colors are relatively unstable and highly sensitive to incident angles, which limit their potential practical applications to a certain extent. Here, we reported a bioinspired color reflector with omnidirectional reflective self-stable (ORS) properties, which is inspired by the wing scales of Papilio palinurus butterfly. Through experimental exploration and theoretical analysis, it was found that the vivid colors of such butterfly wings are structure-based and possess novel ORS properties, which attributes to the multiple optical actions between light and the complex structures coupling the inverse opal-like structures (IOSs) and stacked lamellar ridges (SLRs). On the basis of this, we designed and successfully fabricated the SiO2-base...

Published

2017