Litcius/Paper detail

Relief of excited-state antiaromaticity enables the smallest red emitter

Heechan Kim, Woojin Park, Younghun Kim, Michael Filatov, Cheol Ho Choi, Dongwhan Lee

2021Nature Communications118 citationsDOIOpen Access PDF

Abstract

It is commonly accepted that a large π-conjugated system is necessary to realize low-energy electronic transitions. Contrary to this prevailing notion, we present a new class of light-emitters utilizing a simple benzene core. Among different isomeric forms of diacetylphenylenediamine (DAPA), o- and p-DAPA are fluorescent, whereas m-DAPA is not. Remarkably, p-DAPA is the lightest (FW = 192) molecule displaying red emission. A systematic modification of the DAPA system allows the construction of a library of emitters covering the entire visible color spectrum. Theoretical analysis shows that their large Stokes shifts originate from the relief of excited-state antiaromaticity, rather than the typically assumed intramolecular charge transfer or proton transfer. A delicate interplay of the excited-state antiaromaticity and hydrogen bonding defines the photophysics of this new class of single benzene fluorophores. The formulated molecular design rules suggest that an extended π-conjugation is no longer a prerequisite for a long-wavelength light emission.

Topics & Concepts

AntiaromaticityExcited stateIntramolecular forceMoleculeChemical physicsFluorescencePhotochemistryChemistryMaterials scienceAtomic physicsPhysicsStereochemistryAromaticityOpticsOrganic chemistryLuminescence and Fluorescent MaterialsPhotochemistry and Electron Transfer StudiesSynthesis and Properties of Aromatic Compounds