The emergence of artificial intelligence and the Internet of Things has led to a growing
demand for wearable and maintenance‐free power sources. The continual push toward …

With the ever-growing development of multifunctional and miniature electronics, the
exploring of high-power microwatt-milliwatt self-charging technology is highly essential …

Organic thermoelectric (TE) materials capitalize on advantages such as low thermal
conductivity, low-cost, eco-friendly, versatile processability, light-weight, mechanical …

Thermoelectricity offers a sustainable path to recover and convert waste heat into readily
available electric energy, and has been studied for more than two centuries. From the …

Thermoelectric generators (TEGs) can directly convert waste heat into electrical power. In
the last few decades, most research on thermoelectrics has focused on inorganic bulk …

Assembling thermoelectric modules into fabric to harvest energy from body heat could one
day power multitudinous wearable electronics. However, the invalid 2D architecture of fabric …

Conversion of waste heat to voltage has the potential to significantly reduce the carbon
footprint of a number of critical energy sectors, such as the transportation and electricity …

Conjugated polymers and related processing techniques have been developed for organic
electronic devices ranging from lightweight photovoltaics to flexible displays. These …

In recent years, the substantially improved performance of thermoelectric (TE) materials has
attracted considerable interest in studying the potential applications of the TE technique …

There is a rapidly growing demand for self-powered technologies in wearable electronic
devices that can be integrated with the human body to accomplish various functions …