Bisphosphonium Benzene Diimides

The incorporation of cationic groups onto electron‐poor compounds is a viable strategy for achieving potent electron acceptors, as evidenced by reports of air‐stable radical forms of large aromatic diimides such as naphthalene and perylene diimides. These ions have also been observed to exhibit anio...

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Veröffentlicht in:	Chemistry : a European journal 2024-10, Vol.30 (57), p.e202402791-n/a
Hauptverfasser:	Leake Gebresilassie, Feven, Ji Kim, Min, Castellanos, Daniela, Broderick, Conor H., Ngo, Steven M., Young, Victor G., Cao, Dennis D.
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Sprache:	eng
Schlagworte:	Anions Aromatic compounds Aromatic substitution Benzene Chemical bonds Diimide Electron-deficient compounds Hydrocarbons Incorporation Infrared spectroscopy Naphthalene Phosphine Phosphines Phosphorus Radical ions Reducing agents Strained molecules Substitution reactions
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creator	Leake Gebresilassie, Feven Ji Kim, Min Castellanos, Daniela Broderick, Conor H. Ngo, Steven M. Young, Victor G. Cao, Dennis D.
description	The incorporation of cationic groups onto electron‐poor compounds is a viable strategy for achieving potent electron acceptors, as evidenced by reports of air‐stable radical forms of large aromatic diimides such as naphthalene and perylene diimides. These ions have also been observed to exhibit anion–π interaction tendencies of interest in molecular recognition applications. The benefits of phosphonium incorporation, however, have not yet been extended to the smallest benzene diimides. Here, we report that dibrominated pyromellitic diimide and mellophanic diimide both readily undergo substitution reactions with phosphine sources to yield bisphosphonium compounds. In the single crystalline form, these dications display anion‐π interactions and, in the case of mellophanic diimide, the stabilization of a bromide–water H−bonding ring pattern. The reaction of these dications with chemical reductants readily provides the singly and doubly reduced redox states, which were characterized by UV‐vis spectroscopy and found to exhibit intense absorptions extending into the near‐IR region. Taken together, this work demonstrates that phosphonium incorporation onto congested aromatic diimide scaffolds is synthetically viable and produces unusual electron‐poor compounds. Phosphonium incorporation onto already electron‐deficient benzene diimides is demonstrated here. In the solid state, these compounds engage in interesting anion–π interactions and H−bonding patterns. Injection of electrons is facile (ca. −0.5 V vs Fc/Fc+) and results in species with NIR absorption maxima (λmax up to 821 nm).
doi_str_mv	10.1002/chem.202402791
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These ions have also been observed to exhibit anion–π interaction tendencies of interest in molecular recognition applications. The benefits of phosphonium incorporation, however, have not yet been extended to the smallest benzene diimides. Here, we report that dibrominated pyromellitic diimide and mellophanic diimide both readily undergo substitution reactions with phosphine sources to yield bisphosphonium compounds. In the single crystalline form, these dications display anion‐π interactions and, in the case of mellophanic diimide, the stabilization of a bromide–water H−bonding ring pattern. The reaction of these dications with chemical reductants readily provides the singly and doubly reduced redox states, which were characterized by UV‐vis spectroscopy and found to exhibit intense absorptions extending into the near‐IR region. Taken together, this work demonstrates that phosphonium incorporation onto congested aromatic diimide scaffolds is synthetically viable and produces unusual electron‐poor compounds. Phosphonium incorporation onto already electron‐deficient benzene diimides is demonstrated here. In the solid state, these compounds engage in interesting anion–π interactions and H−bonding patterns. 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Taken together, this work demonstrates that phosphonium incorporation onto congested aromatic diimide scaffolds is synthetically viable and produces unusual electron‐poor compounds. Phosphonium incorporation onto already electron‐deficient benzene diimides is demonstrated here. In the solid state, these compounds engage in interesting anion–π interactions and H−bonding patterns. 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subjects	Anions Aromatic compounds Aromatic substitution Benzene Chemical bonds Diimide Electron-deficient compounds Hydrocarbons Incorporation Infrared spectroscopy Naphthalene Phosphine Phosphines Phosphorus Radical ions Reducing agents Strained molecules Substitution reactions
title	Bisphosphonium Benzene Diimides
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