Isomerization dynamics of a novel cis/trans-only merocyanine
Journal article, 2024

Merocyanines (MC) usually adopt ring opened zwitterionic structures that are interconvertible with their ring-closed spiropyran photoisomers. By methylating the phenolate oxygen, and thereby blocking the ring-closure reaction, a cis/trans-only MC photoswitch was obtained, yielding a perfect candidate for a detailed examination of the cis/trans isomerization mechanism for this class of compounds. This photoswitch displays outstanding properties including excellent photoreaction quantum yields and photoswitching turnovers. Due to the central polymethine bridge of MC, in principle eight cis (C)/trans (T) isomers are possible. Density Functional Theory (DFT) calculations revealed the CCT and TTT-isomers of the studied compound as most stable cis and trans ground state isomers, respectively. UV/vis transient absorption studies combined with conical intersection computations with the complete active space self-consistent field (CASSCF) method show that both trans/cis- and cis/trans-photoisomerizations are initiated by a rotation of the central doubled bond fragment. A hot ground state species is then formed, which undergoes a second isomerization. Thus, the cis/trans reaction proceeds via a CCT-CTT-TTT sequence and the reverse reaction via TTT-TCT-CCT.

quantum chemistry

isomerization pathways

merocyanine

photoswitches

time-resolved spectroscopy

Author

Nadine Blaise

Goethe University Frankfurt

James A. Green

Goethe University Frankfurt

Carlos Benitez-Martin

Chalmers, Chemistry and Chemical Engineering, Chemistry and Biochemistry

Christoph Kaiser

FOM Institute for Atomic and Molecular Physics - AMOLF

Goethe University Frankfurt

Markus Braun

Goethe University Frankfurt

Jonas M. Schaible

Goethe University Frankfurt

Joakim Andreasson

Chalmers, Chemistry and Chemical Engineering, Chemistry and Biochemistry

Irene Burghardt

Goethe University Frankfurt

Josef Wachtveitl

Goethe University Frankfurt

CHEMPHOTOCHEM

2367-0932 (ISSN)

Vol. In Press

Subject Categories

Theoretical Chemistry

Organic Chemistry

DOI

10.1002/cptc.202300327

More information

Latest update

10/3/2024