Carrier Transport in Colloidal Quantum Dot Intermediate Band Solar Cell Materials Using Network Science

Abstract: Colloidal quantum dots (CQDs) have been proposed to obtain intermediate band (IB) materials. The IB solar cell can absorb sub-band-gap photons via an isolated IB within the gap, generating extra electron-hole pairs that increase the current without degrading the voltage, as has been demonstrated experimentally for real cells. In this paper, we model the electron hopping transport (HT) as a network embedded in space and energy so that a node represents the first excited electron state localized in a CQD while a… Show more

“…Sun oriented cell gadgets were characterized beneath standard test conditions (AM1.5G, 100 mW/cm²). Perovskite sun based cells displayed a momentous productivity of 22%, outperforming natural solar cells (9%) and quantum dot-based cells (12%) [22].…”

Advanced Materials for High-Efficiency Solar Cells: A Comprehensive Exploration in Material Science

“…Sun oriented cell gadgets were characterized beneath standard test conditions (AM1.5G, 100 mW/cm²). Perovskite sun based cells displayed a momentous productivity of 22%, outperforming natural solar cells (9%) and quantum dot-based cells (12%) [22].…”

Advanced Materials for High-Efficiency Solar Cells: A Comprehensive Exploration in Material Science

Connecting continuous models of quantum systems to complex networks: Application to electron transport in real-world one dimensional van der Waals materials