Paulina Plochocka1
CNRS1
High environmental stability and surprisingly high efficiency of solar cells based on 2D perovskites have renewed interest in these materials. These natural quantum wells consist of planes of metal-halide octahedra, separated by organic spacers. The unique synergy of soft lattice and opto-electronic properties are often invoked to explain superior characteristic of perovskites materials in applications. At the same time such unique synergy creates fascinating playground for exciton physics which challenges our understanding of this elementary excitation. I will demonstrate that even after decade of intense investigation the notation” unique” so often used in case of perovskites deserves serious scrutiny.<br/>First, I will show that in 2D perovskites, the distortion imposed by the organic spacers governs the effective mass of the carriers. As a result, and unlike in any other semiconductor, the effective mass of the carriers in 2D perovskites can be easily tailored. Secondly, I will highlight controversy related to exciton fine structure in different perovskite compounds and demonstrate that the soft lattice can suppress relaxation of excitons to dark state making 2D perovskites great light emitters. I will further demonstrate the optical evidences of the polaron formation.<br/>In the end I will present excitonic properties in novel type heterostructures: a combination of the monolayer transition metal dichalcogenides with layered organic inorganic perovskites, where spin injection into 2D perovskites has been acheived.