posted on 2021-07-28, 13:04authored bySungwon Song, Seok Joo Yang, Jinhyeok Choi, Se Gyo Han, Kwanghee Park, Hansol Lee, Jiwoo Min, Sunmin Ryu, Kilwon Cho
Dimensionality
engineering is an effective approach to improve
the stability and power conversion efficiency (PCE) of perovskite
solar cells (PSCs). A two-dimensional (2D) perovskite assembled from
bulky organic cations to cover the surface of three-dimensional (3D)
perovskite can repel ambient moisture and suppress ion migration across
the perovskite film. This work demonstrates how the thermal stability
of the bulky organic cation of a 2D perovskite affects the crystallinity
of the perovskite and the optoelectrical properties of perovskite
solar cells. Structural analysis of (FAPbI3)0.95(MAPbBr3)0.05 (FA = formamidinium ion, MA =
methylammonium ion) mixed with a series of bulky cations shows a clear
correlation between the structure of the bulky cations and the formation
of surface defects in the resultant perovskite films. An organic cation
with primary ammonium structure is vulnerable to a deprotonation reaction
under typical perovskite-film processing conditions. Decomposition
of the bulky cations results in structural defects such as iodide
vacancies and metallic lead clusters at the surface of the perovskite
film; these defects lead to a nonradiative recombination loss of charge
carriers and to severe ion migration during operation of the device.
In contrast, a bulky organic cation with a quaternary ammonium structure
exhibits superior thermal stability and results in substantially fewer
structural defects at the surface of the perovskite film. As a result,
the corresponding PSC exhibits the PCE of 21.6% in a reverse current–voltage
scan and a stabilized PCE of 20.1% with an excellent lifetime exceeding
1000 h for the encapsulated device under continuous illumination.