1983
DOI: 10.3891/acta.chem.scand.37b-0459
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Electron-transfer Fluorescence Quenching of Radical Ions.

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Cited by 45 publications
(39 citation statements)
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“…Then DCA •– was excited by the green-light region, giving rise to its excited state, DCA •– *, a highly reactive species with an estimated reducing potential of −3.2 V (vs SCE) 60 and a lifetime of 13.5 ns 61 that allowed it to engage in reductive activation of heteroarene halides. In fact, the electron transfer from DCA •– * would be an exergonic process in all cases, and the trend of substrate reactivity was very accurately mirrored by these thermodynamic data ( Table 5 ).…”
Section: Results and Discussionmentioning
confidence: 99%
“…Then DCA •– was excited by the green-light region, giving rise to its excited state, DCA •– *, a highly reactive species with an estimated reducing potential of −3.2 V (vs SCE) 60 and a lifetime of 13.5 ns 61 that allowed it to engage in reductive activation of heteroarene halides. In fact, the electron transfer from DCA •– * would be an exergonic process in all cases, and the trend of substrate reactivity was very accurately mirrored by these thermodynamic data ( Table 5 ).…”
Section: Results and Discussionmentioning
confidence: 99%
“…The system in Table , entry 3, does not suffer from the problem of an exceedingly short *PC .− lifetime, because *DCA .− is fluorescent and has a comparatively long excited‐state lifetime of circa 5–10 ns depending on the solvent . Electrolysis at a constant cell voltage permits an essentially quantitative conversion of DCA to DCA .− , making selective PC .− photoexcitation straightforward and leading to an overall monophotonic process.…”
Section: The Next Level: Reductive Excited‐state Quenching Followed Bmentioning
confidence: 99%
“…However, the reaction was prematurely terminated due to the formation of a zinc bridge between the cathode and anode that short-circuited the electrochemical setup (entry 8). Anthraquinone (AQ), which exhibits similar light-induced redox reactivities, 9 was also an effective catalyst, albeit with diminished yield (entry 9). Importantly, this reaction was also applicable to the reductive borylation of 4-chloroanisole (3), which has a highly negative reduction potential (Ered = −2.90 V vs SCE) 15 (entry 10).…”
Section: Figure 1 Electrochemical Generation Of Radical Anionmentioning
confidence: 99%
“…For example, cathodic reduction of dicyanoanthracene (DCA; E1/2 = -0.82 V) results in the corresponding radical anion DCA •-, which absorbs visible light and exhibits a strong fluorescence emission (excitation energy E0,0 = 2.38 eV). 9 The photoexcited DCA (DCA •-*) is estimated to display an exceptionally high reducing potential of -3.2 V (vs. SCE), 10 which TD-DFT calculations suggest arises from a SOMO-HOMO level inversion featuring a very unstable electronic structure with a half-filled bonding orbital (ψ1) and a filled antibonding orbital (ψ2) (see Figure S3 in Supporting Information). Strong reductant…”
mentioning
confidence: 99%