Common energy sources include solar radiation (photovoltaic conversion), thermal gradients (thermoelectric generators), kinetic energy from vibrations or motion (piezoelectric, electromagnetic, or electrostatic transduction), and ambient radio frequency energy (rectifying antennas or rectennas). Small-scale wind and hydrodynamic flows are also explored in specialized applications. Each source requires particular converters and power management to optimize energy capture and efficiency.
Because harvested energy is variable, devices typically incorporate energy storage such as rechargeable batteries or supercapacitors and intelligent power-management circuits. Techniques include maximum power point tracking for photovoltaics, voltage boosting or bucking, duty cycling, and event-driven operation to meet application requirements.
Applications include wireless sensor networks, environmental monitoring, wearables and smart textiles, medical implants, automotive sensing, and industrial monitoring. Energy harvesting can extend device lifetime in inaccessible locations or emergency systems where battery replacement is impractical.
Challenges include low and variable power density, environmental dependence, device cost and reliability, integration with other components, and standards for interoperability. Ongoing research focuses on higher-efficiency transducers, multisource harvesters, and advanced storage, as well as ultra-low-power electronics to widen practical use.
The field sees growing interest with the proliferation of the Internet of Things and smart devices, where energy harvesting provides a pathway to maintenance-free or long-life operation. Future developments aim at hybrid harvesters, better materials, and improved energy management to enable pervasive self-powered sensing and actuation.