Abstract
For the prototypical two-dimensional hybrid organic-inorganic perovskites (2D HOIPs) (AE4T)PbX4 (X = Cl, Br, and I), we demonstrate that the Frenkel-Holstein Hamiltonian (FHH) can be applied to describe the absorption spectrum arising from the organic component. We first model the spectra using only the four nearest neighbor couplings between translationally inequivalent molecules in the organic herringbone lattice as fitting parameters in the FHH. We next use linear-response time-dependent density functional theory (LR-TDDFT) to calculate molecular transition densities, from which extended excitonic couplings are evaluated based on the atomic positions within the 2D HOIPs. We find that both approaches reproduce the experimentally observed spectra, including changes in their shape and peak positions. The spectral changes are correlated with a decrease in excitonic coupling from X = Cl to X = I. Importantly, the LR-TDDFT-based approach with extended excitonic couplings not only gives better agreement with the experimental absorption line shape than the approach using a restricted set of fitted parameters but also allows us to relate the changes in excitonic coupling to the underlying geometry. We accordingly find that the decrease in excitonic coupling from X = Cl to Br to I is due to an increase in molecular separation, which in turn can be related to the increasing Pb-X bond length from Cl to I. Our research opens up a potential pathway to predicting optoelectronic properties of new 2D HOIPs from ab initio calculations and to gain insight into structural relations from 2D HOIP absorption spectra.
Highlights
Hybrid organic–inorganic perovskites (HOIPs) are experiencing a meteoric rise as new, low-temperature depositable semiconductors, initially due to the remarkable properties of a group of perovskites as potential solar cell materials,1–9 but currently more broadly as promising, optoelectronic materials for light emitting diodes (LEDs),10–19 chirality-controlled and/or spin-optoelectronic devices,20–22 and other application areas
For the prototypical two-dimensional hybrid organic–inorganic perovskites (2D HOIPs) (AE4T)PbX4 (X = Cl, Br, and I), we demonstrate that the Frenkel–Holstein Hamiltonian (FHH) can be applied to describe the absorption spectrum arising from the organic component
Determining trends in the organic contribution to the absorption spectra of the (AE4T)PbX4 HOIPs is complicated by the presence of the inorganic exciton peak in (AE4T)PbBr4 that obscures the position of the maximum in the organic absorption
Summary
Hybrid organic–inorganic perovskites (HOIPs) are experiencing a meteoric rise as new, low-temperature depositable semiconductors, initially due to the remarkable properties of a group of perovskites as potential solar cell materials, but currently more broadly as promising, optoelectronic materials for light emitting diodes (LEDs), chirality-controlled and/or spin-optoelectronic devices, and other application areas. An organic cation molecule with a low bandgap could participate directly in the functionality of the perovskite by partially contributing to or entirely forming the frontier levels of the overall compound or by accepting excitons from the inorganic framework into emissive organic triplet states.. For the investigation as well as prediction of new 2D HOIPs for, e.g., LED or solar cell applications, it is, necessary to understand the contribution of the organic component to the absorption and emission properties of the perovskite and how the structural properties of the perovskite influence the materials’ spectra. For 3D perovskites, only a limited compositional space is accessible, but when the size of the organic cation is increased, the resulting lower-dimensional hybrid perovskites offer superior chemical stability and a vast set of choices of chemically tunable organic cations. An organic cation molecule with a low bandgap could participate directly in the functionality of the perovskite by partially contributing to or entirely forming the frontier levels of the overall compound or by accepting excitons from the inorganic framework into emissive organic triplet states. In consequence, spectroscopically, the organic contribution can overlap with the inorganic contribution.
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