Piezoelectric energy harvesters (PEHs) have attracted significant attention with the ability of
converting mechanical energy into electrical energy and power the self-powered …

Flexible piezo-pyroelectric hybrid nanogenerators (FPPNG) capable of harvesting body
mechanical and thermal energy are considered as a desirable power supply for the next …

Tremendous popularity is observed for multifunctional flexible electronics with appealing
applications in intelligent electronic skins, human–machine interfaces, and healthcare …

The surface charge density enhancement by incorporating conductive paths into
organic/inorganic piezoelectric composites is considered to be an effective way to achieve …

The piezoelectric charge coefficient (d) and transduction coefficient (d× g) of piezoelectric
materials are the key factors that determine the power generation performance of …

The rapid development of flexible micropower electronics has aided the opportunity for the
broader application of flexible piezoelectric composites (PCs) but has also led to higher …

Flexible piezoelectric energy harvesters (FPEHs) can convert mechanical energy into
electric energy in a manner that powers electronic equipment and systems. Structural design …

The electrical energy obtained by the piezoelectric energy harvesters (PEHs) exhibits high
voltage and low current (ie, high impedance); thus, the electrical impedance needs to be …

Due to the self-supplied energy requirements of wearable electronic devices, flexible
piezoelectric energy harvesters (FPEHs) that can convert the vibration energy in the …

Piezoelectric materials have wide‐ranging applications owing to their capacity to convert
mechanical energy into electrical energy in daily life scenarios. With rapid development in …