Constructing a Surface Multi-cationic Heterojunction for CsPbI 1.5 Br 1.5 Perovskite Solar Cells with Efficiency beyond 14.
Qiufeng YeWenzheng HuYunxiao WeiJunchi ZhuBo YaoKuankuan RenChunhe LiBiyun ShiTie LiFeng YeZebo FangPublished in: The journal of physical chemistry letters (2023)
All-inorganic CsPbI 1.5 Br 1.5 perovskite solar cells are considered as top cell candidates for tandem cells as a result of their excellent thermal stability and photoelectric performance. However, their power conversion efficiencies (PCEs) are still low and far below the theoretical limit mainly as a result of the severe non-radiative recombination and optical loss. Herein, we introduce an versatile method to construct a surface multi-cationic heterojunction to achieve an efficient and stable CsPbI 1.5 Br 1.5 perovskite solar cell. By precisely controlling the content of FA + and MA + on PbBr 2 -rich perovskite films, a high-quality heterojunction layer is formed to help effectively passivate the surface defects and reduce the optical loss of the CsPbI 1.5 Br 1.5 perovskite. In addition, the incorporation of a heterojunction layer can also improve energy-level alignment and reduce interfacial charge recombination loss. As a result, the champion device with the incorporation of SMH exhibits a PCE of 14.11%, which presents the highest reported efficiency for inorganic CsPbI 1.5 Br 1.5 solar cells thus far while retaining 85% of the initial efficiency after 1000 h of storage without encapsulation.
Keyphrases
- perovskite solar cells
- solar cells
- single cell
- room temperature
- dna damage
- high resolution
- cell therapy
- induced apoptosis
- dna repair
- high efficiency
- high speed
- stem cells
- cell cycle arrest
- mesenchymal stem cells
- oxidative stress
- early onset
- cell death
- endoplasmic reticulum stress
- signaling pathway
- ionic liquid
- pi k akt