posted on 2023-09-26, 14:36authored byQiang Fu, Mingqian Chen, Qiaohui Li, Hang Liu, Rui Wang, Yongsheng Liu
Two-dimensional (2D) Ruddlesden-Popper (RP) perovskites
have emerged
as attractive candidates for high-performance perovskite solar cells
(PSCs) thanks to their superior environmental and structural stability.
However, 2D RP PSCs exhibit larger exciton binding energy due to the
dielectric mismatch between the organic and inorganic layers, resulting
in poorer photovoltaic performance compared to their 3D analogs. Here,
we developed a selenophene-based spacer, namely, 2-selenophenemethylammonium
(SeMA), for stable and efficient 2D RP PSCs. The 2D perovskite film
using methylammonium (MA) as the A-site cation (nominal n = 5) shows excellent film quality with large grain size and a preferred
vertical orientation relative to the substrate. Furthermore, we have
successfully demonstrated the effectiveness of a predeposition transport
layer (PDTL) consisting of [6,6]-phenyl-C61-butyric acid methyl ester
(PCBM) in passivating surface defects of the perovskite film and inducing
densification of the upper PCBM electron transport layer. This densification
promotes efficient extraction and transport of electrons. The optimized
PSCs based on 2D RP perovskite using MA as A-site cation (nominal n = 5) achieved a power conversion efficiency (PCE) of 17.25%,
which was further boosted to 19.03% when using formamidinium (FA)
as A-site cation. This represents a record PCE of 2D RP PSCs by using
the selenophene-based spacer. Moreover, these 2D RP PSCs significantly
improve thermal, moisture, and light stability. Our results provide
significant implications for the synergistic strategy of developing
selenophene-based spacers and device engineering methods for achieving
highly efficient and stable 2D RP perovskite solar cells.