Your search keyword '"Kim, Heechan"' showing total 2 results

1. Single‐Benzene Dual‐Emitters Harness Excited‐State Antiaromaticity for White Light Generation and Fluorescence Imaging.

Author

Kim, Younghun, Kim, Heechan, Son, Jung Bae, Filatov, Michael, Choi, Cheol Ho, Lee, Nam Ki, and Lee, Dongwhan

Subjects

*INTRAMOLECULAR proton transfer reactions, *ANTIAROMATICITY, *FLUORESCENCE, *SMALL molecules, *TAUTOMERISM, *HYDROGEN bonding

Abstract

Molecular emitters simultaneously generating light at different wavelengths have wide applications. With a small molecule, however, it is challenging to realize two independent radiative pathways. We invented the first examples of dual‐emissive single‐benzene fluorophores (SBFs). Two emissive tautomers are generated by synthetic modulation of the hydrogen bond acidity, which opens up pathways for excited‐state proton transfer. White light is produced by a delicate balance between the energy and intensity of the emission from each tautomer. We show that the excited‐state antiaromaticity of the benzene core itself dictates the proton movements driving the tautomer equilibrium. Using this simple benzene platform, a fluorinated SBF was synthesized with a record high solubility in perfluorocarbon solvents. White light‐emitting devices and multicolor imaging of perfluorocarbon nanodroplets in live cells demonstrate the practical utility of these molecules. [ABSTRACT FROM AUTHOR]

Published

2023

2. Relief of excited-state antiaromaticity enables the smallest red emitter.

Author

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

Subjects

INTRAMOLECULAR proton transfer reactions, ANTIAROMATICITY, INTRAMOLECULAR charge transfer, STOKES shift, VISIBLE spectra, HYDROGEN bonding

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. Commonly, large π-conjugated systems facilitate low-energy electronic transitions. Here, the authors demonstrate that the relief of excited-state antiaromaticity of the benzene core leads to large Stokes shifts, and allows the construction of emitters covering the entire visible spectrum without the need of extending π-conjugation. [ABSTRACT FROM AUTHOR]

Published

2021