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π-Extended push–pull azo-pyrrole photoswitches: synthesis, solvatochromism and optical band gaps

J. A. Balam-Villarreal, B. J. López-Mayorga, David Gallardo‐Rosas, Rubén A. Toscano, M. P. Carreón-Castro, Vladimir A. Basiuk, Fernando Cortés‐Guzmán, José G. López‐Cortés, M. Carmen Ortega‐Alfaro

2020Organic & Biomolecular Chemistry38 citationsDOI

Abstract

A new family of push-pull biphenyl-azopyrrole compounds 3b-g and 4b-d was efficiently obtained via a Suzuki cross-coupling reaction between 2-(4'-iodophenyl-azo)-N-methyl pyrrole (1a) or 3-(4'-iodophenyl-azo)-1,2,5-trimethyl pyrrole (2a) and 4'-substituted phenyl boronic acids in excellent yields. The influence of the π-biphenyl backbone and pyrrole pattern substitution was correlated with their optical properties. Solvatochromic studies via UV-visible spectrophotometry revealed that the inclusion of a 4'-nitro-biphenyl fragment favors a red-shift of the main absorption band in these azo compounds compared with their non-substituted analogues. Likewise, optical band-gaps were estimated by means of electronic absorption spectra and correlated with TD-DFT studies. The pyrrole pattern substitution and the π-conjugated backbone exhibit a clear influence on their thermal isomerization kinetics at room temperature. In all cases, biphenylazo-pyrrole compounds lead to the formation of J-type aggregates in binary MeOH : H2O solvents. Under these conditions, compounds 3b-c undergo a water-assisted cis-to-trans isomerization at room temperature.

Topics & Concepts

SolvatochromismChemistryPhotochemistryPyrrolePhotoswitchAzobenzeneBand gapVisible spectrumCombinatorial chemistryMoleculeOptoelectronicsOrganic chemistryPhysicsPhotochromic and Fluorescence ChemistryPorphyrin and Phthalocyanine ChemistryMolecular Sensors and Ion Detection