With the arrival of the Internet of Things (IoTs) era, there is a growing requirement for
systems with many sensor nodes in a variety of fields of applications. The demands for …

Synapses are essential for the transmission of neural signals. Synaptic plasticity allows for
changes in synaptic strength, enabling the brain to learn from experience. With the rapid …

Simulating biological synapses with electronic devices is a re‐emerging field of research. It
is widely recognized as the first step in hardware building brain‐like computers and artificial …

The human somatosensory system, consisting of receptors, transmitters, and synapses,
functions as the medium for external mechanical stimuli perception and sensing signal …

Fibrous energy–autonomy electronics are highly desired for wearable soft electronics,
human–machine interfaces, and the Internet of Things. How to effectively integrate various …

Compared with the traditional von Neumann architecture, neural systems have many
distinctive properties including parallelism, low-power consumption, fault tolerance, self …

Nowadays, there is a high demand for sensitive and selective real-time analytical methods
suitable for a wide range of applications, from personalized telemedicine, drug discovery …

Sensory adaptation is an essential part of biological neural systems for sustaining human
life. Using the light-induced halide phase segregation of CsPb (Br1–x I x) 3 perovskite, we …

Energy‐harvesting electronic skin (E‐skin) is highly promising for sustainable and self‐
powered interactive systems, wearable human health monitors, and intelligent robotics …

As key components of artificial afferent nervous systems, synaptic devices can mimic the
physiological synaptic behaviors, which have attracted extensive attentions. Here, a flexible …