AI Article Synopsis
- Thin porphyrin films used in optical devices and photovoltaics exhibit different electronic and optical properties compared to their gas-phase forms, which could be tailored through ligand or substituent modifications.
- The study uses density functional theory and many-body perturbation theory to analyze how crystallization affects the electronic levels and optical properties of porphyrins, revealing a reduced HOMO-LUMO gap due to polarization effects.
- Results indicate a higher energy shift of the HOMO level and a notable redshift in excitation bands, except for the Q bands, suggesting that further engineering of band gaps can be achieved by adjusting the polarizability through ligand modifications.
Article Abstract
Thin porphyrin films as employed in modern optical devices or photovoltaic applications show deviating electronic and optical properties from the gasphase species. Any understanding of the physical origin may pave way to a specific engineering of these properties via ligand or substituent control. Here we investigate the impact of crystallization of prototypical porphyrins on the electronic levels and optical properties in the framework of density functional theory and many-body perturbation theory. Crystallization substantially shrinks the HOMO-LUMO gap based on polarization effects. We find a shift of the HOMO to higher energy is consistent with recent experiment of MgTPP multilayer film on Ag (100) [A. Classen et al., Phys. Rev. B, 2017, 95, 115414]. Calculated excitation spectra demonstrate a significant redshift of excitation bands except for the Q bands. These lowest excitation bands, in stark contrast to the strong HOMO-LUMO gap renormalization, remain essentially the same as in the gas phase. Our work underlines the possibility of band-gap engineering via ligand-controlled modification of the polarizability.
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| http://dx.doi.org/10.1039/c9cp06040e | DOI Listing |
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