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Main Authors: Wiethorn, Zachary R., Hunter, Kye E., Montoya-Castillo, Andrés, Zuehlsdorff, Tim J.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.02687
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_version_ 1866912105553199104
author Wiethorn, Zachary R.
Hunter, Kye E.
Montoya-Castillo, Andrés
Zuehlsdorff, Tim J.
author_facet Wiethorn, Zachary R.
Hunter, Kye E.
Montoya-Castillo, Andrés
Zuehlsdorff, Tim J.
contents Porphyrins offer a malleable and cost-efficient platform to sculpt bioinspired technologies with tunable charge transfer, energy conversion, and photocatalytic properties. Yet, despite decades of research, the physical mechanisms that determine their electronic spectra remain elusive. Even for metal-free porphyrins, no consensus exists on the origin of the splitting of their $Q$-bands, an energetic region critical in photosynthesis. We leverage our recent statistical treatment of molecular motions in the condensed phase to predict their linear absorption spectra. By bridging exact quantum-dynamical expressions with atomistic simulations, our theory is the first to capture the spectra of representative porphyrins in solution: porphine, tetraphenylporphyrin, and tetraphenylporpholactone. Our work reveals that $Q$-band splitting arises from extreme timescale separation of nuclear motions that turn symmetry-forbidden transitions bright. We exploit these insights to propose and confirm how chemical modifications tune the optical properties of porphyrins, demonstrating the potential for developing design principles to tailor their optoelectronic behavior.
format Preprint
id arxiv_https___arxiv_org_abs_2411_02687
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Symmetry breaking fluctuations split the porphyrin Q bands
Wiethorn, Zachary R.
Hunter, Kye E.
Montoya-Castillo, Andrés
Zuehlsdorff, Tim J.
Chemical Physics
Porphyrins offer a malleable and cost-efficient platform to sculpt bioinspired technologies with tunable charge transfer, energy conversion, and photocatalytic properties. Yet, despite decades of research, the physical mechanisms that determine their electronic spectra remain elusive. Even for metal-free porphyrins, no consensus exists on the origin of the splitting of their $Q$-bands, an energetic region critical in photosynthesis. We leverage our recent statistical treatment of molecular motions in the condensed phase to predict their linear absorption spectra. By bridging exact quantum-dynamical expressions with atomistic simulations, our theory is the first to capture the spectra of representative porphyrins in solution: porphine, tetraphenylporphyrin, and tetraphenylporpholactone. Our work reveals that $Q$-band splitting arises from extreme timescale separation of nuclear motions that turn symmetry-forbidden transitions bright. We exploit these insights to propose and confirm how chemical modifications tune the optical properties of porphyrins, demonstrating the potential for developing design principles to tailor their optoelectronic behavior.
title Symmetry breaking fluctuations split the porphyrin Q bands
topic Chemical Physics
url https://arxiv.org/abs/2411.02687