Extended basis <i>ab</i><i>initio</i> calculations on conformers of propanal

Gupta, Vikram

doi:10.1139/v85-164

Cited by 6 publications

(2 citation statements)

References 15 publications

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“…The addition of a methylene group introduces the complexity that several rotational conformers are now possible. Spectroscopic and theoretical work have shown that two stable conformers exist in the ground electronic state. ,− In the cis conformation, the methyl group is eclipsed with the oxygen atom (OCCC dihedral angle = 0°) whereas the skew conformation has the OCCC dihedral angle at approximately 128°. The cis conformer is found to be more stable by 5 kJ mol -1 with a barrier of 9 kJ mol -1 separating the cis and skew minima .…”

Section: Introductionmentioning

confidence: 99%

Near Threshold Photochemistry of Propanal. Barrier Height, Transition State Structure, and Product State Distributions for the HCO Channel

2002

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The photodissociation dynamics of propanal have been investigated at photolysis wavelengths between 300 and 327 nm. The threshold for production of HCO fragments was found to be 326.26 nm, which corresponds to 30645 cm-1 (366.6 kJ mol-1) above the zero-point of the S 0 state. From known thermochemical data, this threshold lies 25.0 ± 3.6 kJ mol-1 above the bond dissociation energy. The nascent HCO rotational and translational energy distributions were determined following dissociation at threshold. The rotational population was measured as a function of N, K a, K c, and S. The distribution of rotational states followed a Gaussian function with an average rotational energy of 2.5 ± 0.5 kJ mol-1. The population of the near-degenerate spin-rotation states was equal, while the population in the asymmetry doublets favored the upper energy component by about 3:1. Careful measurement of the Doppler profiles of individual K a = 0 lines in the LIF spectrum revealed that the translational energy also shows a Gaussian-like distribution with an average energy of 6.5 ± 1.0 kJ mol-1. The ethyl fragment must also have an average translational energy of 6.5 ± 1.0 kJ mol-1 and therefore an average internal energy of 9.5 kJ mol-1 is inferred. The observed energy partitioning in the fragments is consistent with a model in which the HCO rotational and translational excitation is determined mostly by the transition state geometry, a barrier on the triplet surface, and the fixed energy in the exit channel. A modified impulsive model was satisfactory in reproducing the energy deposited into the various degrees of freedom. The model implied impact parameters at infinite separation corresponding to an in-plane HCO angle of 40° and an out-of-plane angle of 60°. The strongly pyramidal nature of the transition state produces more angular momentum about the b axis than the c axis, which causes the preference for the upper energy component of the asymmetry doublets.

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Section: Introductionmentioning

confidence: 99%

Near Threshold Photochemistry of Propanal. Barrier Height, Transition State Structure, and Product State Distributions for the HCO Channel

2002

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“…A quantitative measurement of the width of several nonoverlapped peaks in the spectrum was made by scanning very slowly over the peak several times and averaging the scans to get a final peak profile. Measurements were performed for qRo (7), qRo (10), qRo (12), qRo(13), qRo (19), qRo (20), qPo(3), and qPo(5) transitions. The splitting of transitions corresponding to Ka ^0 prevented us from making meaningful sub-Doppler measurements as there were no cases for which both the spin-rotation and asymmetry splitting were fully resolved.…”

Section: Resultsmentioning

confidence: 99%

Nascent state distribution of HCO photoproduct arising from 309 nm photolysis of propionaldehyde

Terentis¹,

Knepp²,

Kable³

1995

J. Phys. Chem.

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The photodissociation dynamics of jet-cooled propionaldehyde have been investigated at a wavelength of 309.1 nm by monitoring the resultant nascent HCO fragments by laser induced fluorescence spectroscopy.HCO was formed only in the %(O,O,O) state. The population distribution of different rotational states characterized by Nand K, is reasonably described by a Boltzmann distribution at a temperature of 480 f 50 K, which corresponds to an average energy in rotation of 6.0 f 0.6 kJ mol-'. Careful measurement of the width of individual K, = 0 lines in the LIF spectrum revealed that the average translational energy of the fragments is 23 f 4 kJ mol-' of HCO. These measurements have allowed us to estimate that the ethyl radical sibling fragment is born with almost no internal energy. The observed energy partitioning in the fragments is consistent with a model in which the HCO rotational and translational excitation is determined mostly by the fixed energy in the exit channel. By analogy with acetaldehyde and considering the lack of vibrational excitation, the barrier to dissociation is predicted to lie around 15 kJ mol-' below the photon energy.

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On the origin of π-facial diastereoselectivity in nucleophilic additions to chiral carbonyl compounds. 1. Rotational profiles of propionaldehyde 1, chloroacetaldehyde 2, and 2-chloropropionaldehyde 3.

1991

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Extended basis abinitio calculations on conformers of propanal

Cited by 6 publications

References 15 publications

Near Threshold Photochemistry of Propanal. Barrier Height, Transition State Structure, and Product State Distributions for the HCO Channel

Near Threshold Photochemistry of Propanal. Barrier Height, Transition State Structure, and Product State Distributions for the HCO Channel

Nascent state distribution of HCO photoproduct arising from 309 nm photolysis of propionaldehyde

On the origin of π-facial diastereoselectivity in nucleophilic additions to chiral carbonyl compounds. 1. Rotational profiles of propionaldehyde 1, chloroacetaldehyde 2, and 2-chloropropionaldehyde 3.

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