Theoretical Studies of the Thermal Gas-Phase Decomposition of Vinyl Bromide on the Ground-State Potential-Energy Surface

Abrash, Samuel A.; Zehner, Robert W.; Mains, Gilbert J.; Raff, Lionel M.

doi:10.1021/j100010a005

Cited by 51 publications

(123 citation statements)

References 12 publications

(20 reference statements)

Supporting

Mentioning

118

Contrasting

Order By: Relevance

“…As a reference, the geometry and vibrational frequencies of the neutral molecule were also calculated; the results summarized in Tables 2-4 are in good agreement with experimental data and previous calculations reported by Abrash et al [30]. Tables 2 and 3.…”

Section: Computational Resultssupporting

confidence: 84%

Photoelectron spectroscopy of vinylbromide and intramolecular dynamics of the ionic B̃ state

et al. 2000

View full text Add to dashboard Cite

In this paper, we report the He(I) photoelectron spectrum (PES) and the threshold-photoelectron (TPES) spectrum of C 2 H 3 Br. The fine structure observed in the first two ionic states in the He(I) spectrum is assigned to progressions belonging partially to previously unobserved vibrational normal modes. The TPES has been measured between 9.0 and 25.0 eV, and the photon energy range of 9.8-12.0 eV has been investigated in more detail. Extensive calculations with the GAUSSIAN set of programs have been performed to help in the assignment of the observed features. Furthermore, a conical intersection between the Ã 2 A" and the 2 A" states was found to take place along the C-Br stretching coordinate. Intramolecular dynamics of the 2 A" state, initially prepared in the Frank-Condon region, was probed by the Fourier transform of the spectrum. The 2 A" state is almost readily depleted, most probably due to a very effective internal conversion through the conical intersection.

show abstract

Section: Computational Resultssupporting

confidence: 84%

Photoelectron spectroscopy of vinylbromide and intramolecular dynamics of the ionic B̃ state

et al. 2000

View full text Add to dashboard Cite

show abstract

“…[22] The Br channel carrying a smaller translational energy was anticipated to originate from the dissociation of the ground state and its yield was reported to be one order of magnitude smaller than that of the HBr elimination. [23,24] In contrast to this case, the HBr product was not found in recent studies of the photodissociation of 1,2-dibromoethylene which were carried out at 248 nm by using product translational spectroscopy (PTS). [11] Lin and co-workers proposed the two exclusive dissociation channels Br 2 + C 2 H 2 and BrA C H T U N G T R E N N U N G (fast) + BrA C H T U N G T R E N N U N G (slow) + C 2 H 2 with a branching ratio of about 0.2:0.8.…”

mentioning

confidence: 74%

Photodissociation of 1,2‐Dibromoethylene at 248 nm: Br₂ Molecular Elimination Probed by Cavity Ring‐Down Absorption Spectroscopy

et al. 2008

View full text Add to dashboard Cite

The Br2 elimination channel is probed for 1,2-C2H2Br2 in the B(3)Pi(+)ou-X(1)Sigma(+)g transition upon irradiation at 248 nm by using cavity ring-down absorption spectroscopy (CRDS). The nascent vibrational population ratio of Br2(v=1)/Br2(v=0) is obtained to be 0.7+/-0.2, thus indicating that the Br2 fragment is produced in hot vibrational states. The obtained Br2 products are anticipated to result primarily from photodissociation of the ground-state cis isomer via four-center elimination or from cis/trans isomers via three-center elimination, each mechanism involving a transition state that has a Br-Br distance much larger than that of ground state Br2. According to ab initio potential energy calculations, the pathways that lead to Br2 elimination may proceed either through the electronic ground state by internal conversion or through the triplet state by intersystem crossing. Temperature-dependence measurements are examined, thereby supporting the pathway that involves internal conversion--which was excluded previously by using product translational spectroscopy (PTS). The quantum yield for the Br2 elimination reaction is determined to be 0.120.1, being substantially contributed by the ground-state Br2 product. The discrepancy of this value from that (of 0.2) obtained by PTS may rise from the lack of measurements in probing the triplet-state Br2 product.

show abstract

“…On the ground-state surface, this is the major dissociation channel at internal energies below 6.00 eV. 6 On the excited-state surfaces, however, we find that such dissociations do not occur. None of the 3700 trajectories computed in this study gave HBr as a product.…”

Section: Bmentioning

confidence: 56%

“…6 In that investigation, we found that at internal energies equal to the photon energy in the photolytic experiments2 (6.44 eV), the simulated TOF spectrum obtained from the calculated distribution of translational energies subsequent to HBr elimination is in fair accord with the time-offlight measurementse2 As the excitation energy decreases, the degree of agreement between the computed and measured TOF spectra decreases. It was therefore suggested that the HBr observed in the photolytic beam experiments2 is being produced subsequent to internal conversion to the ground state.…”

Section: Bmentioning

confidence: 78%

Theoretical Studies of the Photolytic Decomposition of Vinyl Bromide at 193 nm

Mains¹,

Raff²,

Abrash³

1995

J. Phys. Chem.

Self Cite

View full text Add to dashboard Cite

The decomposition dynamics of vinyl bromide upon single-photon excitation at 193 nm have been investigated by using classical trajectory methods on adiabatic excited-state potentials that have been obtained by using empirical and a b initio configuration interaction (CI) methods. The excited-state potential surfaces are represented by a global analytic hypersurface previously developed for the vinyl bromide ground state with the C-Br bonding Morse-type potential replaced with one of the repulsive C-Br interactions obtained in the empirical or ab initio calculations Energetic considerations suggest that the dissociation dynamics of vinyl bromide upon photolysis at 193 nm involves excitation to three or four repulsive C-Br states which include the A'A"(na*), 63A"(na*) and C3A'(no*) potentials. The effects of a vertical excitation from the ground state to the A'A"(na*) and E3A'(na*) states have been determined by the computation of 300 or more trajectories in each case. The results show that the only products for these excitations are vinyl radicals and either Br(2P3n) or Br (2Pln) atoms. No HBr is observed. This result is consistent with the hypothesis advanced in our previous study of vinyl bromide dissociation on the ground-state surface where we suggested that the HBr formed in previously reported beam experiments [Zsr. J. Chem. 1989,29, 3831 is produced subsequent to internal conversion to the ground state. Combination of the trajectory results with the measured Br/HBr ratio of 1.28 indicates that the internal conversion probability lies in the range 0.44-0.64. The calculated translational energy distributions for C2H3 and either Br(2P3n) or Br(2Pln) atoms are peaked at energiessignificantly in excess of that observed in the beam experiments. This is interpreted to mean that the ab initio excited-state potentials are too repulsive. Comparison with the experimental data suggests that, in the region around the C-Br equilibrium distance, the ab initio energies are too large by about 16 kcdmol. The computed full width at half-maximum for all distributions is much smaller than the experimental result, suggesting that decomposition is occurring from more than one excited electronic surface. It is shown that a good fit to the measured translational energy distribution can be obtained from a linear combination of the distributions computed by using three empirical potentials whose energy at the equilibrium C-Br separation has been reduced by about 16 kcaYmol from that predicted by the ab initio calculations. The values of the expansion coefficients indicate that about 60% of the bromine atoms are formed in the 2P3n ground state. This is close to the statistical result based upon a simple count of available spin states.

show abstract

Theoretical Studies of the Thermal Gas-Phase Decomposition of Vinyl Bromide on the Ground-State Potential-Energy Surface

Cited by 51 publications

References 12 publications

Photoelectron spectroscopy of vinylbromide and intramolecular dynamics of the ionic B̃ state

Photoelectron spectroscopy of vinylbromide and intramolecular dynamics of the ionic B̃ state

Photodissociation of 1,2‐Dibromoethylene at 248 nm: Br₂ Molecular Elimination Probed by Cavity Ring‐Down Absorption Spectroscopy

Theoretical Studies of the Photolytic Decomposition of Vinyl Bromide at 193 nm

Contact Info

Product

Resources

About

Theoretical Studies of the Thermal Gas-Phase Decomposition of Vinyl Bromide on the Ground-State Potential-Energy Surface

Cited by 51 publications

References 12 publications

Photoelectron spectroscopy of vinylbromide and intramolecular dynamics of the ionic B̃ state

Photoelectron spectroscopy of vinylbromide and intramolecular dynamics of the ionic B̃ state

Photodissociation of 1,2‐Dibromoethylene at 248 nm: Br2 Molecular Elimination Probed by Cavity Ring‐Down Absorption Spectroscopy

Theoretical Studies of the Photolytic Decomposition of Vinyl Bromide at 193 nm

Contact Info

Product

Resources

About

Photodissociation of 1,2‐Dibromoethylene at 248 nm: Br₂ Molecular Elimination Probed by Cavity Ring‐Down Absorption Spectroscopy