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Device design optimization with interface engineering for highly efficient mixed cations and halides perovskite solar cells

Mohammed Benali Kanoun, Ahmed‐Ali Kanoun, A.E. Merad, Souraya Goumri‐Said

2020Results in Physics33 citationsDOIOpen Access PDF

Abstract

Mixed cations and halides perovskite materials in solar cells further enhance the goal of achieving higher efficiency and long-term stability at low cost for manufacturing. In this work, a numerical simulation based on device modeling is directed to explore the effect of defect density, perovskite layer thickness, doping density, hole transport layers, on the cell performance of the composite perovskite devices. Our outcomes revealed that the optimal thickness of mixed perovskite absorber is obtained around 400 nm. Therefore, several potential inorganic hole transport layers are investigated. The results show that mixed perovskite with PTAA and Cu2O as hole transport layers are the most suitable materials and efficient systems owing to their enhanced hole transport and high electric conductivity. Moreover, the optimum defect density parameter should be ordered under ~1015 cm3. Further simulations were handled to examine the impact of electron affinity in interface layers on the achievement of solar cells. Two interface layers are introduced into the device model by considering the interface carrier recombination.

Topics & Concepts

Perovskite (structure)HalideMaterials scienceDopingOptoelectronicsConductivityInterface (matter)Work (physics)Density functional theoryElectron mobilityChemical physicsChemistryInorganic chemistryComposite materialComputational chemistryPhysical chemistryThermodynamicsCrystallographyPhysicsCapillary numberCapillary actionPerovskite Materials and ApplicationsChalcogenide Semiconductor Thin FilmsQuantum Dots Synthesis And Properties
Device design optimization with interface engineering for highly efficient mixed cations and halides perovskite solar cells | Litcius