Periodic Reporting for period 1 - SAMA (Solution-processed All-perovskite Multi-junction Architectures for Flexible and Printable Solar Cells)
Reporting period: 2022-03-17 to 2024-03-16
We later developed a narrow band gap material that is composed of a Pb/Sn mixture to create a tandem architecture. This work involved the incorporation of the formamidinium (FA+ ) and caesium as replacement cation for methylammonium MA+ . As we have shown in our previous work, the (FA,Cs)Pb(Br,I)3 perovskite is significantly more thermally stable than its MA-based counterpart. However, we identify a significant challenge, where these cations have a significantly lower solubility in the ACN/MA solvent system. Hence, we explored the alkylamine group in hopes of identifying a methylamine replacement that can solubilize these more thermally stable cations in an aprotic solvent that will not damage the underlying perovskite layer. Wo observed that many of the amines could actually dissolve the precursor formamidinium-based tin/lead precursor salts. For example, we were able to fabricate a (FA(1-x)MAx)Pb(Br(1-y)Iy)3 perovskite film using an acetonitrile solvent mixed with n-butylamine CH₃(CH2)₃NH2, diethylamine (CH₃CH2)2NH, Isopropylamine (C3H9N) and dipropylamine (C6H15N). Although thin films were able to form a perovskite film, for most compositions, residual 2D material from the chosen amine would reside in the film. We conducted thorough crystallographic and optical band gap studies on these films to fully characterize them.