Foldable electronics, with the advantages of size compactness and shape transformation, are promising for portable and wearable applications. The challenge for realizing foldable devices is exploiting highly foldable conductive substrates free from deformation under large strain. In this work, highly foldable and degradable transparent conductive substrates were constructed using similar to 20 mu m ultrathin regenerated cellulose film (RCF) substrates to reduce strain, embedding silver nanowires (AgNWs) into RCFs to improve the interface binding force, as well as improving the adhesive strength of AgNWs junction. The AgNWs/RCF complex with an initial sheet resistance of 14 O/sq maintained an electrical conductivity after either single foldi...
We present new flexible, transparent, and conductive coatings composed of an annealed silver nanowir...
With recent emergence of wearable electronic devices, flexible and stretchable transparent electrode...
Abstract Flexible conducting films in the forms of bendability or stretchability are developed as a ...
It is of great challenge to develop a transparent solid state electrochromic device which is foldabl...
Recently, flexible transparent conductive films have received widespread attention as important comp...
The emergence of flexible and stretchable optoelectronics has motivated the development of new trans...
Transparent conductors for the next generation of soft electronic devices need to be highly stretcha...
Transparent microelectrodes with high bendability are necessary to develop lightweight, small electr...
We present highly flexible transparent electrodes composed of silver nanowire (AgNW) networks and si...
The unstable mechanical properties of flexible transparent conductive films (TCFs) make it difficult...
We report on a new surface modifier which simultaneously improves electrical, optical, and mechanica...
We synthesized silver nanowires (AgNWs) with a mean diameter of about 120 nm and 20–70 μm i...
Huge challenges remain regarding the facile fabrication of neat metallic nanowires mesh for high-qua...
We develop highly robust and stretchable conductive transparent electrodes based on silver nanowires...
Mechanically ultra-robust, transparent and flexible electrodes assembled from silver nanowires (Ag N...
We present new flexible, transparent, and conductive coatings composed of an annealed silver nanowir...
With recent emergence of wearable electronic devices, flexible and stretchable transparent electrode...
Abstract Flexible conducting films in the forms of bendability or stretchability are developed as a ...
It is of great challenge to develop a transparent solid state electrochromic device which is foldabl...
Recently, flexible transparent conductive films have received widespread attention as important comp...
The emergence of flexible and stretchable optoelectronics has motivated the development of new trans...
Transparent conductors for the next generation of soft electronic devices need to be highly stretcha...
Transparent microelectrodes with high bendability are necessary to develop lightweight, small electr...
We present highly flexible transparent electrodes composed of silver nanowire (AgNW) networks and si...
The unstable mechanical properties of flexible transparent conductive films (TCFs) make it difficult...
We report on a new surface modifier which simultaneously improves electrical, optical, and mechanica...
We synthesized silver nanowires (AgNWs) with a mean diameter of about 120 nm and 20–70 μm i...
Huge challenges remain regarding the facile fabrication of neat metallic nanowires mesh for high-qua...
We develop highly robust and stretchable conductive transparent electrodes based on silver nanowires...
Mechanically ultra-robust, transparent and flexible electrodes assembled from silver nanowires (Ag N...
We present new flexible, transparent, and conductive coatings composed of an annealed silver nanowir...
With recent emergence of wearable electronic devices, flexible and stretchable transparent electrode...
Abstract Flexible conducting films in the forms of bendability or stretchability are developed as a ...
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