The electronic spectrum of linear pentadiynylidene in comparison with isomeric ethynylcyclopropenylidene
Literature Information
Publication Date
2002-06-06
DOI
10.1039/B200608C
Impact Factor
3.676
Authors
Andreas Mavrandonakis, Max Mühlhäuser, George E. Froudakis, Sigrid D. Peyerimhoff
View Original
Abstract
Approximate transition energies and oscillator strengths are computed with large-scale multi-reference configuration interaction calculations to differentiate between linear pentadiynylidene HC5H and its Cs symmetric isomer ethynylcyclopropenylidene HC3C2H by certain fingerprints in their electronic spectra. The first dipole-allowed transition of the HC5H spectrum is obtained at 2.76 eV (3Σ−u ← X 3Σ−g) in reasonable agreement with experimental measurements of 434 nm (2.86 eV) in neon matrix. The oscillator strength of 3Σ−u ← X 3Σ−g of linear HC5H is computed with f = 0.007, a value similar to what we obtain for linear HC7H (f = 0.005). In addition a second very strong 3Σ−u ← X3Σ−g transition is predicted by the calculations around 7.3 eV. The yet-to-be-observed electronic spectrum of HC3C2H is characterized by four strong transitions calculated at 4.79 eV (2 1A″), 6.17 eV (2 1A′), 7.27 eV (3 1A′) and 7.74 eV (4 1A′). The first transition of HC3C2H 1 1A″ ← X 1A′ is calculated to be very weak and at much higher energy (3.64 eV) than the first 3Σ−u ← X 3Σ−g transition of the linear isomer.
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Physical Chemistry Chemical Physics
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