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Published October 28, 2021 | Accepted Version + Supplemental Material
Journal Article Open

Making Nitronaphthalene Fluoresce

Rybicka-Jasińska, Katarzyna ORCID icon
Espinoza, Eli M. ORCID icon
Clark, John A. ORCID icon
Derr, James B. ORCID icon
Carlos, Gregory
Morales, Maryann ORCID icon
Billones, Mimi Karen
O'Mari, Omar ORCID icon
Ågren, Hans ORCID icon
Baryshnikov, Glib V. ORCID icon
Vullev, Valentine I. ORCID icon

Abstract

Nitroaromatic compounds are inherently nonfluorescent, and the subpicosecond lifetimes of the singlet excited states of many small nitrated polycyclic aromatic hydrocarbons, such as nitronaphthalenes, render them unfeasible for photosensitizers and photo-oxidants, despite their immensely beneficial reduction potentials. This article reports up to a 7000-fold increase in the singlet-excited-state lifetime of 1-nitronaphthalene upon attaching an amine or an N-amide to the ring lacking the nitro group. Varying the charge-transfer (CT) character of the excited states and the medium polarity balances the decay rates along the radiative and the two nonradiative pathways and can make these nitronaphthalene derivatives fluoresce. The strong electron-donating amine suppresses intersystem crossing (ISC) but accommodates CT pathways of nonradiate deactivation. Conversely, the N-amide does not induce a pronounced CT character but slows down ISC enough to achieve relatively long lifetimes of the singlet excited state. These paradigms are key for the pursuit of electron-deficient (n-type) organic conjugates with promising optical characteristics.

Additional Information

© 2021 American Chemical Society. Received 3 July 2021. Accepted 8 October 2021. Published online 15 October 2021. Published in issue 28 October 2021. This research was funded by the USA National Science Foundation (grant number CHE 1800602 and AGEP supplement fellowship for J.A.C.), the American Chemical Society Petroleum Research Fund (grant number 60651-ND4), and the USA National Institutes of Health, National Eye Institute (grant R01 EY027440). G.V.B. extends his gratitude to the Swedish Research Council for their financial support (Starting Grant No. 2020-04600). The quantum-chemical calculations were performed with computational resources provided by Swedish National Infrastructure for Computing (SNIC 2020-3-29) at the High-Performance Computing Center North (HPC2N) partially funded by the Swedish Research Council through the Grant Agreement No. 2018-05973. Author Contributions: K.R.J. and E.M.E. contributed equally. The authors declare no competing financial interest. This paper was published ASAP on October 15, 2021, with errors in the main text. The corrected version was reposted on October 19, 2021.

Attached Files

Accepted Version - nihms-1768796.pdf

Supplemental Material - jz1c02155_si_001.pdf

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Additional details

Identifiers Funding Dates
Created:
August 22, 2023
Modified:
October 23, 2023