Photophysical and Theoretical Investigations of Oligo(p-phenyleneethynylene)s: Effect of Alkoxy Substitution and Alkyne−Aryl Bond Rotations

James, P. V. ; Sudeep, P. K. ; Suresh, C. H. ; Thomas, K. George (2006) Photophysical and Theoretical Investigations of Oligo(p-phenyleneethynylene)s: Effect of Alkoxy Substitution and Alkyne−Aryl Bond Rotations The Journal of Physical Chemistry A, 110 (13). pp. 4329-4337. ISSN 1089-5639

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Official URL: http://doi.org/10.1021/jp055184o

Related URL: http://dx.doi.org/10.1021/jp055184o

Abstract

The unique photophysical, conformational, and electronic properties of two model phenyleneethynylene-based rigid rod molecular systems, possessing dialkoxy substitutions, are reported in comparison with an unsubstituted system. Twisting of the phenyl rings along the carbon-carbon triple bond is almost frictionless in these systems giving rise to planar as well as several twisted ground-state conformations, and this results in broad structureless absorption in the spectral region of 250-450 nm. In the case of 1,4-bis(phenylethynyl)benzene, a broad absorption band was observed due to the HOMO-LUMO transition, whereas dialkoxy-substituted compounds possess two well-separated bands. Dialkoxy substitution in the 2,5-position of the phenyl ring in phenyleneethynylenes alters its central arene pi-orbitals through the resonance interaction with oxygen lone pairs resulting in similar orbital features for HOMO and HOMO-1/HOMO-2. Electronic transition from the low-lying HOMO-1/HOMO-2 orbital to LUMO results in the high-energy band, and the red-shifted band originates from the HOMO-LUMO transition. The first excited-state transition energies at different dihedral angles, calculated by the TDDFT method, indicate that the orthogonal conformation has the highest excitation energy with an energy difference of 15 kcal/mol higher than the low-lying planar conformation. The emission of these compounds originates preferentially from the more relaxed planar conformation resulting in well-defined vibronic features. The fluorescence spectral profile and lifetimes were found to be independent of excitation wavelengths, confirming the existence of a single emitting species.

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ID Code:127590
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