Can energy harvesting be used for indoor applications?

Moreover, harvesting energy from light has demonstrated its capability as a means to achieve battery-free applications (Brunelli et al., 2009, Wang et al., 2016). However, when it comes to considering energy harvesting for indoor applications, the difficulty in characterizing the harvestable power becomes substantial.

What is gcell energy harvesting?

GCell is an indoor Energy Harvesting (EH) technology, otherwise known as power harvesting or energy scavenging. It is the process by which ambient energy, in this case light, is captured and converted directly into electricity for a wide range of indoor and portable products.

Are iPSCs a good solution for low-light energy harvesting?

By leveraging the unique optoelectronic properties of perovskites, such as tunable bandgaps and superior light absorption, IPSCs have emerged as a promising solution for low-light energy harvesting, particularly in environments dominated by artificial light sources like LEDs and FLs.

Can light energy harvesting be used in outdoor environments?

Past research has proven the viability of this approach in outdoor environments (Shaikh and Zeadally, 2016). In an indoor environment, where radiated levels are low, light energy harvesting has been identified as an effective method to provide enough power to low-power electronic systems such as wireless sensor networks (Matiko et al., 2014).

What are the benefits of PV technology for indoor energy harvesting?

The emerging PV technologies have shown amazing capabilities for indoor energy harvesting, displaying high power conversion efficiency, good flexibility, and champion-specific powers.

Can indoor light be used as a new energy source?

Calculations validated using an instrumented energy harvesting prototype. Indoor light can be used as a new energy source to power µW low consumption wireless sensor networks (WSNs), but for wireless electronic devices consuming tens of mW, it is still challenging.