Baig, M. W., Pederzoli, M., Kývala, M., & Pittner, J. (2024). Quantum Chemical and Trajectory Surface Hopping Molecular Dynamics Study of Iodine-based BODIPY Photosensitizer. arXiv preprint arXiv:2411.10893.
This study aims to computationally investigate the photophysical properties of I-BODIPY, an iodine-substituted BODIPY derivative, and assess its potential as a triplet photosensitizer for singlet oxygen generation.
The researchers employed a combination of quantum chemical calculations and trajectory surface hopping (TSH) molecular dynamics (MD) simulations. They benchmarked various TD-DFT functionals against higher-level methods like ADC(2) and CASPT2 to select the most appropriate functional for describing the excited-state properties of I-BODIPY. They then performed TSH MD simulations, incorporating nonadiabatic effects and spin-orbit couplings, to study the relaxation processes in I-BODIPY after photoexcitation.
The computational study confirms the high efficiency of I-BODIPY as a triplet photosensitizer, capable of generating singlet oxygen with a high quantum yield. The study highlights the importance of iodine substitution in enhancing intersystem crossing rates, leading to efficient triplet state population.
This research contributes to the understanding of the photophysical processes in iodine-substituted BODIPY derivatives, particularly their potential for photodynamic therapy. The findings provide valuable insights for designing and developing efficient photosensitizers for various applications.
The study primarily focuses on the gas-phase dynamics of I-BODIPY. Future research could explore the influence of solvent effects on the excited-state dynamics and singlet oxygen generation efficiency. Further investigations could also involve studying the interaction of I-BODIPY with biological targets to assess its efficacy in photodynamic therapy settings.
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