The development of flexible piezoelectric nanogenerators has experienced rapid progress
in the past decade and is serving as the technological foundation of future state-of-the-art …

Self-powered devices and micro-sensors are in high demand for intelligent electronics and
flexible wearables for applications in medical healthcare and human–computer interactive …

Tactile perception includes the direct response of tactile corpuscles to environmental stimuli
and psychological parameters associated with brain recognition. To date, several artificial …

Electronic skins (e-skins) are devices that can respond to mechanical stimuli and enable
robots to perceive their surroundings. A great challenge for existing e-skins is that they may …

The performance of conventional computer based on von Neumann architecture is limited
due to the physical separation of memory and processor. By synergistically integrating …

Wearable blood‐pressure sensors have recently attracted attention as healthcare devices
for continuous non‐invasive arterial pressure (CNAP) monitoring. However, the accuracy of …

Skin-interfaced electronics is gradually changing medical practices by enabling continuous
and non-invasive tracking of physiological and biochemical information. With the rise of big …

Electronic skins (e-skins) have seen intense research and rapid development in the past two
decades. To mimic the capabilities of human skin, a multitude of flexible/stretchable sensors …

Force sensors based on triboelectric nanogenerator (TENG) technology show promising
applications in wearable electronics due to the significant advantages in biomechanical …

Human-machine interfaces (HMIs) are important windows for a human to communicate with
the outside world. The current HMI devices such as cellphones, tablets, and computers can …