Flexible devices are emerging as important applications for future display, robotics, in vitro
diagnostics, advanced therapies, and energy harvesting. In this review, we provide an …

Conducting fibres and yarns promise to become an essential part of the next generation of
wearable electronics that seamlessly integrate electronic function into one of the most …

Smart wearable electronic textiles (e-textiles) that can detect and differentiate multiple
stimuli, while also collecting and storing the diverse array of data signals using highly …

There has been a steady progress in develo** synthetic fibers in the past few years.
Bicomponent fibers and nanofibers in a core/shell (C/S) configuration, including two …

Recent advances in ubiquitous low-power electronics call for the development of light-
weight and flexible energy sources. The textile format is highly attractive for unobtrusive …

Due to a variety of outstanding properties, such as large surface area, high length-to-
diameter ratio, flexible surface functionality, tunable surface morphologies and superior …

This study reports on the poling and characteristics of a melt-spun piezoelectric
bicomponent fiber with poly (vinylidene fluoride)(PVDF) as its sheath component and a …

We report an all-polymer flexible piezoelectric fiber that uses both judiciously chosen
geometry and advanced materials in order to enhance fiber piezoelectric response. The …

The environmental pollutions caused by rising usage of nonrenewable energy sources
spurred researchers to investigate alternative energy systems that can collect energy from …

The development and popularity of wearable electronics increase demand for wearable
energy harvesters that can scavenge energy from environment or human body movements …