Skin-like ionogels have attracted much attention in artificial electronic skins and wearable
sensors. However, it is challenging to develop ionogel-based multifunctional sensors that …

Flexible sensors based on ionogels show great potential in wearable devices because of
their compliance and deformability. However, ionogel sensors usually suffer from low …

Human fingers exhibit both high sensitivity and wide tactile range. The finger skin structures
are designed to display gradient microstructures and compressibility. Inspired by the …

We report a new method to fabricate highly stretchable and highly conductive fluorescent
ionogels via self-catalytic cross-linking of poly (ionic liquid (IL))-based copolymers …

Stretchable devices function at the biology/electrode interface, depending on the excellent
conformality between electronic components and nonplanar surfaces. Various polymeric …

Ionic conductive soft materials for mimicking human skin are a promising topic since they
can be thought of as a possible basis for biomimetic sensing. In pursuit of devices with a …

Here, we report a simple method for preparing muscle-mimetic highly tough, conductive, and
stretchable liquid crystalline ionogels which contains only one poly (ionic liquid)(PIL) in an …

Due to the rapid development of multi-functional flexible wearable sensors, the development
prospects of ionohydrogels with excellent mechanical properties and high sensitivity are …

Developing multifunctional stretchable ionic skin (I-Skin) to mimic the sensations of the
human skin is of great interest and shows promising potential in wearable sensors and …

Ionic liquid (IL)-based gels (ionogels), which consist of ILs and polymer networks, are
emerging materials with extraordinary properties, such as good ionic conductivity …