Abstract
The topic explores advances in innovative high-end technological developments that revolutionize energy loading schemes through high-energy storage capacity. A highly efficient energy conversion mechanism for photoelectron charging and discharging systems is engineered. The result is a smart energy storage design that is sustainable and conforms to a smart energy distribution with zero energy losses through the transmission infrastructure. The topic unpacks the choice of chalcogenide materials previously known to have exceptional photoelectrochemical properties and their innovative morphological manipulation into few-layered thin films of metal chalcogenides such as InxSey, MoxSy, InxTiySez, MoxSey, and many other photoelectrochemical materials. These materials have been used to fabricate supercapacitors, solar cells, sensors, batteries, and other superior smart energy conversion and storage devices. These latest innovative smart storage devices composed of photoelectrochemical materials have paved the attainment of high-end, highly efficient smart storage devices that have translated into the advancement of artificial intelligence and remote technologies including robotic devices, drones, satellite equipment. The two-step innovative smart energy devices are characterized by advanced mechanisms of high quantum energy packing and then smart discharge and energy deployment with minimum of zero losses during transmission.