Issue 42, 2021

Understanding the influence of geometric and electronic structure on the excited state dynamical and photoredox properties of perinone chromophores

Abstract

In this work, a series of eight similarly structured perinone chromophores were synthesized and photophysically characterized to elucidate the electronic and structural tunability of their excited state properties, including excited state redox potentials and fluorescence lifetimes/quantum yields. Despite their similar structure, these chromophores exhibited a broad range of visible absorption properties, quantum yields, and excited state lifetimes. In conjunction with static and time-resolved spectroscopies from the ultrafast to nanosecond time regimes, time-dependent computational modeling was used to correlate this behavior to the relationship between non-radiative decay and the energy-gap law. Additionally, the ground and excited state redox potentials were calculated and found to be tunable over a range of 1 V depending on the diamine or anhydride used in their synthesis (Ered* = 0.45–1.55 V; Eox* = −0.88 to −1.67 V), which is difficult to achieve with typical photoredox-active transition metal complexes. These diverse chromophores can be easily prepared, and with their range of photophysical tunability, will be valuable for future use in photofunctional applications.

Graphical abstract: Understanding the influence of geometric and electronic structure on the excited state dynamical and photoredox properties of perinone chromophores

Supplementary files

Article information

Article type
Paper
Submitted
23 Aug 2021
Accepted
14 Oct 2021
First published
14 Oct 2021

Phys. Chem. Chem. Phys., 2021,23, 24200-24210

Author version available

Understanding the influence of geometric and electronic structure on the excited state dynamical and photoredox properties of perinone chromophores

K. A. Wells, J. R. Palmer, J. E. Yarnell, S. Garakyaraghi, B. C. Pemberton, J. M. Favale, M. K. Valchar, A. Chakraborty and F. N. Castellano, Phys. Chem. Chem. Phys., 2021, 23, 24200 DOI: 10.1039/D1CP03870B

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