Bin Cai scite author profile

Aerogels assembled from colloidal metal or semiconductor nanocrystals (NCs) feature large surface area, ultralow density, and high porosity, thus rendering them attractive in various applications, such as catalysis, sensors, energy storage, and electronic devices. Morphological and structural modification of the aerogel backbones while maintaining the aerogel properties enables a second stage of the aerogel research, which is defined as hierarchical aerogels. Different from the conventional aerogels with nanowire-like backbones, those hierarchical aerogels are generally comprised of at least two levels of architectures, i.e., an interconnected porous structure on the macroscale and a specially designed configuration at local backbones at the nanoscale. This combination "locks in" the inherent properties of the NCs, so that the beneficial genes obtained by nanoengineering are retained in the resulting monolithic hierarchical aerogels. Herein, groundbreaking advances in the design, synthesis, and physicochemical properties of the hierarchical aerogels are reviewed and organized in three sections: i) pure metallic hierarchical aerogels, ii) semiconductor hierarchical aerogels, and iii) metal/semiconductor hybrid hierarchical aerogels. This report aims to define and demonstrate the concept, potential, and challenges of the hierarchical aerogels, thereby providing a perspective on the further development of these materials.

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High‐Performance Flexible Pressure Sensor with a Self‐Healing Function for Tactile Feedback

Yang

et al. 2022

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High-performance flexible pressure sensors have attracted a great deal of attention, owing to its potential applications such as human activity monitoring, man-machine interaction, and robotics. However, most high-performance flexible pressure sensors are complex and costly to manufacture. These sensors cannot be repaired after external mechanical damage and lack of tactile feedback applications. Herein, a high-performance flexible pressure sensor based on MXene/polyurethane (PU)/interdigital electrodes is fabricated by using a low-cost and universal spray method. The sprayed MXene on the spinosum structure PU and other arbitrary flexible substrates (represented by polyimide and membrane filter) act as the sensitive layer and the interdigital electrodes, respectively. The sensor shows an ultrahigh sensitivity (up to 509.8 kPa -1 ), extremely fast response speed (67.3 ms), recovery speed (44.8 ms), and good stability (10 000 cycles) due to the interaction between the sensitive layer and the interdigital electrodes. In addition, the hydrogen bond of PU endows the device with the self-healing function. The sensor can also be integrated with a circuit, which can realize tactile feedback function. This MXene-based high-performance pressure sensor, along with its designing/fabrication, is expected to be widely used in human activity detection, electronic skin, intelligent robots, and many other aspects.

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Refractive Index Control and Rayleigh Scattering Properties of Transparent TiO₂ Nanohybrid Polymer

et al. 2009

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The surface of TiO2 nanoparticles (NPs) was modified by a coupling agent of 2-(3,4-epoxycyclohexyl)ethyltrimethoxysilane to render them highly compatible with organic monomer mixtures avoiding aggregation. Such TiO2 NPs were then chemically attached with a prepolymer. The refractive index of hybrid TiO2 NPs-polymer was increased dramatically in comparison with that of pure polymer, and it can be controlled by adjusting the content of TiO2 NPs. The Rayleigh scattering of hybrid TiO2 NPs-polymer was size-dependent and increased with the increase of the TiO2 NPs content. When Rayleigh scattering of the hybrid material prepared with a milling and centrifuge process was significantly lowered, one can obtain a transparent sample, which is good for optical devices.

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Ultra-broadband terahertz absorption by exciting the orthogonal diffraction in dumbbell-shaped gratings

Zang

Shi

Chen

et al. 2015

Sci Rep

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Metamaterials, artificial electromagnetic media consisting of periodical subwavelength metal-based micro-structures, were widely suggested for the absorption of terahertz (THz) waves. However, they have been suffered from the absorption of THz waves just in the single-frequency owing to its resonance features. Here, in this paper, we propose a simple periodical structure, composed of two 90 degree crossed dumbbell-shaped doped-silicon grating arrays, to demonstrate broadband THz wave absorption. Our theoretical and experimental results illustrate that THz waves can be efficiently absorbed more than 95% ranging from 0.92 THz to 2.4 THz. Such an ultra-wideband polarization-independent THz absorber is realized mainly based on the mechanisms of the anti-reflection effect together with the [±1, 0]-order and [0, ±1]-order grating diffractions. The application of our investigation can be extend to THz couplers, filters, imaging, and so on.

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Large volume metrology process models: A framework for integrating measurement with assembly planning

et al. 2008

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Bin Cai

Emerging Hierarchical Aerogels: Self‐Assembly of Metal and Semiconductor Nanocrystals

High‐Performance Flexible Pressure Sensor with a Self‐Healing Function for Tactile Feedback

Refractive Index Control and Rayleigh Scattering Properties of Transparent TiO₂ Nanohybrid Polymer

Ultra-broadband terahertz absorption by exciting the orthogonal diffraction in dumbbell-shaped gratings

Large volume metrology process models: A framework for integrating measurement with assembly planning

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Bin Cai

Emerging Hierarchical Aerogels: Self‐Assembly of Metal and Semiconductor Nanocrystals

High‐Performance Flexible Pressure Sensor with a Self‐Healing Function for Tactile Feedback

Refractive Index Control and Rayleigh Scattering Properties of Transparent TiO2 Nanohybrid Polymer

Ultra-broadband terahertz absorption by exciting the orthogonal diffraction in dumbbell-shaped gratings

Large volume metrology process models: A framework for integrating measurement with assembly planning

Contact Info

Product

Resources

About

Refractive Index Control and Rayleigh Scattering Properties of Transparent TiO₂ Nanohybrid Polymer