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Thiophene‐Containing Pechmann Dyes and Related Compounds: Synthesis, and Experimental and DFT Characterisation
Author(s) -
Kantchev Eric Assen B.,
Norsten Tyler B.,
Tan Marilyn L. Y.,
Ng Joey J. Y.,
Sullivan Michael B.
Publication year - 2012
Publication title -
chemistry – a european journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.687
H-Index - 242
eISSN - 1521-3765
pISSN - 0947-6539
DOI - 10.1002/chem.201101903
Subject(s) - thiophene , chemistry , alkyl , substituent , conformational isomerism , chromophore , heteroatom , ring (chemistry) , photochemistry , dihedral angle , stereochemistry , organic chemistry , molecule , hydrogen bond
Abstract Attaching 2‐thienyl residues to the Pechmann dye core chromophore (5,5‐ exo ‐dilactone situated around a CC double bond) results in a novel magenta‐coloured compound (UV/Vis spectroscopy λ max =570 nm in CHCl 3 ), which can be rearranged to a yellow 6,6‐ endo ‐dilactone ( λ max =462 nm in CHCl 3 ). Single and double amidation results in pronounced redshift in the 5,5‐ exo series (violet, λ max =570 nm and blue, λ max =606 nm in CHCl 3 , respectively) but pronounced blueshift in the 6,6‐ endo series (yellow, λ max =424 nm and pale yellow bordering on colourless, λ max =395 nm in CHCl 3 , respectively). Incorporation of a 3‐alkyl substituent on the thiophene ring allows for sharp increase of solubility in organic solvents concomitant with fine‐tuning of the colour: a redshift in 5,5‐ exo ‐dilactones but a blueshift in 5,5‐ exo ‐dilactams. DFT computations demonstrate that both lactone classes are planar regardless of the presence of a 3‐alkyl group. The lactam derivatives are non‐planar: the thiophene‐core chromophore dihedral angles increase on going from 5,5‐ exo to 6,6‐ endo and from thiophene to 3‐alkyl thiophene. Depending on the core heteroatom (O vs. N‐alkyl), ring junction (5,5‐ exo vs. 6,6‐ endo ) and 3‐thiophene substituent (H vs. alkyl), two, three, four or six conformers are possible. All of these conformers were characterised by DFT and were found to be very close in energy at both IEFPCM/B3LYP/DGDZVP and SMD/M06/DGDZVP levels of theory. Within each conformer set, the HOMO and LUMO energies were within 0.05 eV and the predicted λ max values (TD‐DFT) within 10 nm, and this implies low sensitivity of the optical and electronic properties to conformation. Cyclic voltammetry measurements of selected compounds demonstrated good matching to the HOMO and LUMO energies from IEFPCM/B3LYP/DGDZVP computations. M06‐2X was the best DFT functional for TD‐DFT, giving predicted λ max values within about 20 nm.