Trapped-Hydrogen-Induced Energy Loss in Tin-Based Hybrid Perovskite Solar Cells
Access status:
Open Access
Type
ArticleAuthor/s
Liang, YuhangCui, Xiangyuan
Li, Feng
Stampfl, Catherine
Ringer, Simon Peter
Huang, Jun
Zheng, Rongkun
Abstract
The hitherto subdued power conversion efficiencies of Sn-based hybrid perovskite solar cells are generally attributed to severe nonradiative recombination; however, the responsible deep-level defects are still unclear. Here, we report an important nonradiative energy loss mechanism ...
See moreThe hitherto subdued power conversion efficiencies of Sn-based hybrid perovskite solar cells are generally attributed to severe nonradiative recombination; however, the responsible deep-level defects are still unclear. Here, we report an important nonradiative energy loss mechanism in the prototypical FASnI3 [FA = HC(NH2)2, formamidinium]. High-density tin vacancies (𝑉Sn) can effectively capture hydrogen to form 𝑉Sn −H2 complexes that act as highly detrimental nonradiative recombination centers. We quantitatively show that they can give rise to strong carrier recombination and thus energy loss due to a high nonradiative recombination rate constant. These key findings identify a hidden yet critical origin for the low performance of FASnI3-based devices and highlight the significance of controlling the hydrogen environment in the development of broad high-efficiency nontoxic halide perovskite device applications.
See less
See moreThe hitherto subdued power conversion efficiencies of Sn-based hybrid perovskite solar cells are generally attributed to severe nonradiative recombination; however, the responsible deep-level defects are still unclear. Here, we report an important nonradiative energy loss mechanism in the prototypical FASnI3 [FA = HC(NH2)2, formamidinium]. High-density tin vacancies (𝑉Sn) can effectively capture hydrogen to form 𝑉Sn −H2 complexes that act as highly detrimental nonradiative recombination centers. We quantitatively show that they can give rise to strong carrier recombination and thus energy loss due to a high nonradiative recombination rate constant. These key findings identify a hidden yet critical origin for the low performance of FASnI3-based devices and highlight the significance of controlling the hydrogen environment in the development of broad high-efficiency nontoxic halide perovskite device applications.
See less
Date
2022Source title
Physical Review AppliedVolume
18Issue
3Publisher
APS Physical Review JournalsLicence
OtherFaculty/School
Faculty of Science, School of PhysicsFaculty of Engineering, School of Aerospace Mechanical and Mechatronic Engineering
Faculty of Engineering, School of Chemical and Biomolecular Engineering
Share