Solar Cells Integrated With TriboElectric NanoGenerator Work When It Rains

Solar cells, as promising devices for converting light into electricity, have a dramatically reduced performance on rainy days Researchers from University of California  Los Angeles (UCLA) have built  an energy harvesting structure that integrates a solar cell and a triboelectric nanogenerator (TENG) device. Objective: to realize power generation from both sunlight and raindrops.

A heterojunction silicon (Si) solar cell is integrated with a TENG by a mutual electrode. Regarding the solar cell, imprinted PEDOT:PSS is used to reduce light reflection, which leads to an enhanced short-circuit current density. A single-electrode-mode water-drop TENG on the solar cell is built by combining imprinted polydimethylsiloxane (PDMS) as a triboelectric material combined with a PEDOT:PSS layer as an electrode. The increasing contact area between the imprinted PDMS and water drops greatly improves the output of the TENG.

The hybrid energy harvesting system integrated electrode configuration can combine the advantages of high current level of a solar cell and high voltage of a TENG device, promising an efficient approach to collect energy from the environment in different weather conditions.



How To Scavenge Simultaneously Solar And Wind Energy

To realize the sustainable energy supply in a smart city, it is essential to maximize energy scavenging from the city environments for achieving the self-powered functions of some intelligent devices and sensors.

solar and wind powered houseAlthough the solar energy can be well harvested by using existing technologies, the large amounts of wasted wind energy in the city cannot be eectively utilized since conventional wind turbine generators can only be installed in remote areas due to their large volumes and safety issues.
Here, the researchers from the Chinese Academy of Sciences rationally design a hybridized nanogenerator, including a solar cell (SC) and a triboelectric nanogenerator (TENG), that can individually/simultaneously scavenge solar and wind energies, which can be extensively installed on the roofs of the city buildings. Under the same device area of about 120 mm × 22 mm, the SC can deliver a largest outputpower of about 8 mW, while the output power of the TENG can be up to 26 mW. Impedance matching between the SC and TENG has been achieved by using a transformer to decrease the impedance of the TENG. The hybridized nanogenerator has a larger output current and a better charging performance than that of the individual SC or TENG.
This research presents a feasible approach to maximize solar and wind energies scavenging from the city environments with the aim to realize some self-powered functions in smart city.