Litcius/Paper detail

Roles of bandgrading, lifetime, band alignment, and carrier concentration in high-efficiency CdSeTe solar cells

X. Zheng, Eric Colegrove, Joel N. Duenow, John Moseley, Wyatt K. Metzger

2020Journal of Applied Physics35 citationsDOIOpen Access PDF

Abstract

CdSeTe alloying has significantly increased the efficiency of CdTe-based solar technology. Here, computational modeling compares how different CdSeTe bandgrading, carrier lifetimes, band alignment, and carrier concentrations contribute to transport, recombination, and performance. We find that the gain in photocurrent caused by bandgap narrowing alone is insufficient to describe experimental efficiency gains. Performance can be increased by adjusting CdSeTe compositions and bandgrading depths. However, these performance gains are small relative to the contributions of enhanced lifetime by Se alloying, which can explain record cell efficiency gains with minimal open-circuit voltage loss despite significant bandgap narrowing. Similarly, CdSeTe band alignment shifts can significantly increase performance if front interface recombination is prevalent. For a wide range of CdSeTe grading profiles, the hole density is a critical component to achieve efficiencies exceeding 25%.

Topics & Concepts

PhotocurrentMaterials scienceOptoelectronicsBand gapCadmium telluride photovoltaicsWide-bandgap semiconductorCarrier lifetimeOpen-circuit voltageVoltageSiliconElectrical engineeringEngineeringChalcogenide Semiconductor Thin FilmsQuantum Dots Synthesis And PropertiesPerovskite Materials and Applications
Roles of bandgrading, lifetime, band alignment, and carrier concentration in high-efficiency CdSeTe solar cells | Litcius