Issue 31, 2019

Fluorenylporphyrins functionalized by electrochromic ruthenium units as redox-triggered fluorescence switches

Abstract

Two dyads containing tris- and tetrakis-meso-fluorenyl-substituted porphyrin and ethynylruthenium units, 1 and 2, were investigated by emission spectro-electrochemical (SEC) methods for their potential use as fluorescence switches. The ruthenium group as a potential electron donor and the porphyrin as a potential electron acceptor are connected by a phenylene bridge in 1 and by a fluorenylene bridge in 2. The new fluorenyl-linked dyad 2 was probed by UV-visible, near-infrared (NIR) and infrared (IR) absorption SEC methods, and the properties interpreted with the aid of hybrid-DFT computations, for comparison with reported data for 1. The porphyrin-based fluorescence of 1 decreased in intensity upon oxidation to 1+ and decreased further on oxidising 1+ to 12+. A much weaker change in the fluorescence intensity of 2 was observed upon oxidation to 2+ but the intensity decreased upon subsequent oxidation of 2+ to 22+. These findings contrast with data reported for some other porphyrins appended with redox-active ruthenium or iron units, where fluorescence intensities increase upon oxidation of the peripheral metal centers, but they match data reported more recently for closely related arrays. A rationale for these apparently contrasting observations is proposed.

Graphical abstract: Fluorenylporphyrins functionalized by electrochromic ruthenium units as redox-triggered fluorescence switches

Supplementary files

Article information

Article type
Paper
Submitted
20 May 2019
Accepted
09 Jul 2019
First published
10 Jul 2019

Dalton Trans., 2019,48, 11897-11911

Fluorenylporphyrins functionalized by electrochromic ruthenium units as redox-triggered fluorescence switches

X. Zhang, S. Abid, L. Shi, J. A. G. Williams, M. A. Fox, F. Miomandre, C. Tourbillon, J. Audibert, O. Mongin, F. Paul and C. O. Paul-Roth, Dalton Trans., 2019, 48, 11897 DOI: 10.1039/C9DT02087J

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