Your search keyword '"R. P. H. Rettschnick"' showing total 7 results

1. ChemInform Abstract: Inelastic Scattering of Rotationally Excited Glyoxal by H2 at E = 80 meV

Author

R. P. H. Rettschnick and G.‐J. Kroes

Subjects

Angular momentum, chemistry.chemical_compound, Chemistry, Excited state, Energy transfer, Glyoxal, General Medicine, Atomic physics, Inelastic scattering, Quantum, Excitation

Abstract

Results of quantum calculations on rotationally and vibrationally inelastic scattering of rotationally excited 1Au(S1) trans‐glyoxal (in collisions with H2, at a collision energy of 80 meV) are reported. These results are used to assess the influence of sequential collisions on a recent experiment on glyoxal +H2. For ‖ΔK‖>3, the cross sections for rotationally inelastic scattering σ(00,K=k→00,K’=K+ΔK) depend exponentially on (ΔK)2 (and not on the energy difference between the initial and final states), which shows that the rotationally inelastic scattering is dominated by angular momentum transfer rather than by energy transfer. Taking into account sequential collisions leads to a substantial improvement in the agreement between the calculated and experimental values of the rotationally resolved cross sections for excitation of the lowest frequency ν7 torsional mode.

Published

2010

2. Inelastic scattering of rotationally excited glyoxal by H2 at E=80 meV

Author

G.‐J. Kroes and R. P. H. Rettschnick

Subjects

Angular momentum, chemistry.chemical_compound, Chemistry, Energy transfer, Excited state, General Physics and Astronomy, Torsion (mechanics), Glyoxal, Physical and Theoretical Chemistry, Atomic physics, Inelastic scattering, Quantum, Excitation

Abstract

Results of quantum calculations on rotationally and vibrationally inelastic scattering of rotationally excited 1Au(S1) trans‐glyoxal (in collisions with H2, at a collision energy of 80 meV) are reported. These results are used to assess the influence of sequential collisions on a recent experiment on glyoxal +H2. For ‖ΔK‖>3, the cross sections for rotationally inelastic scattering σ(00,K=k→00,K’=K+ΔK) depend exponentially on (ΔK)2 (and not on the energy difference between the initial and final states), which shows that the rotationally inelastic scattering is dominated by angular momentum transfer rather than by energy transfer. Taking into account sequential collisions leads to a substantial improvement in the agreement between the calculated and experimental values of the rotationally resolved cross sections for excitation of the lowest frequency ν7 torsional mode.

Published

1991

3. Rotationally and vibrationally inelastic scattering of glyoxal by helium at an energy of 96 meV

Author

David C. Clary, G.-J. Kroes, and R. P. H. Rettschnick

Subjects

Angular momentum, chemistry, Deuterium, Scattering, Molecular vibration, General Physics and Astronomy, chemistry.chemical_element, Physical and Theoretical Chemistry, Atomic physics, Inelastic scattering, Inelastic neutron scattering, Excitation, Helium

Abstract

Results of quantum calculations on rotationally and vibrationally inelastic scattering from four vibrational levels of 1 A u (S 1 ) trans-glyoxal (in collisions with helium, at a collision energy of 96 meV) are reported. The results can serve as predictions to be borne out by experiments that have already been carried out, but have not been analyzed yet. The calculations predict that rotationally inelastic scattering should be similar for scattering from the 0 0 , 5 1 and 8 1 levels, but different for scattering from the 7 2 level. A comparison of the glyoxal+He results with results for scattering of vibrationless deuterated glyoxal also presented here shows that, at a collision energy of 96 meV, rotational excitation of glyoxal by helium is governed by angular momentum transfer rather than by energy transfer. Vibrationally inelastic scattering is dominated by the lowest frequency ν 7 torsional mode, but the calculations predict that transitions involving other vibrational modes should also be observable.

Published

1990

4. Rotationally and vibrationally inelastic scattering of glyoxal at E=80 meV

Author

R. P. H. Rettschnick, C. E. Dateo, G.-J. Kroes, and David C. Clary

Subjects

Elastic scattering, chemistry.chemical_compound, Cross section (physics), Chemistry, Scattering, Excited state, General Physics and Astronomy, Glyoxal, Fermi resonance, Physical and Theoretical Chemistry, Atomic physics, Inelastic scattering, Excitation

Abstract

Results of quantum calculations on rotationally and vibrationally inelastic scattering of 1Au(S1) trans‐glyoxal by H2,He, and Ar(E=80 meV) are presented. For scattering of 00 glyoxal and 72 glyoxal by H2, a quantitative comparison with a recent crossed beam experiment is made. The calculated cross sections for rotationally inelastic scattering are in good agreement with the experimental values, and the trend that σ(72, k=0→72, k’) falls off faster with k’ than σ(00, k=0→00, k’) is reproduced. Our calculations do not reproduce the experimental finding that, for the initial 72 level, the cross sections for the Δv7=−1 and Δv7=+1 transitions are nearly identical. The calculations on 72 glyoxal + He and Ar show important differences with 72 glyoxal + H2 in the competition of rotational excitation with vibrational excitation. Model calculations also presented here yield some interesting trends in the k’ dependence of the cross sections σ(00, k=0→x1, k’) on the vibrational mode x excited.

Published

1990

5. Rotationally inelastic scattering of glyoxal by H2 at E=80 meV

Author

R. P. H. Rettschnick and G.‐J. Kroes

Subjects

Angular momentum, Scattering, Chemistry, Monte Carlo method, General Physics and Astronomy, Inelastic scattering, Schrödinger equation, Cross section (physics), symbols.namesake, symbols, Physical and Theoretical Chemistry, Atomic physics, Excitation, Beam (structure)

Abstract

Using the Monte Carlo classical trajectory (CT) method and the azimuthal close‐coupled, infinite‐order sudden (ACC‐IOS) method, we have calculated cross sections for rotational excitation of S1 trans‐glyoxal by H2 at E=80 meV. The cross sections σ(k=0, j→k’) calculated with the CT method are nearly independent of j. The classical values of σ(k=0, j=5→k’) are in good agreement with the quantum values of σ(k=0→k’) for 2≤k’≤12, although the quantum calculations show a slight preference for odd Δk transitions which is not found in the CT calculations. Both the CT results and the ACC‐IOS results are in good agreement with results obtained in a recent crossed beam experiment. Rotational excitation to high k’ (k’=11,12) occurs by collisions of H2 with one of the H atoms of glyoxal, and the initial value of the orbital angular momentum approximately equals the final value of k in such collisions. Since backward scattering is dominant in collisions leading to high k’, angular momentum constraints alone cannot expl...

Published

1990

6. ChemInform Abstract: Rotationally and Vibrationally Inelastic Scattering of Glyoxal at E=80 meV

Author

C. E. Dateo, David C. Clary, G.-J. Kroes, and R. P. H. Rettschnick

Subjects

chemistry.chemical_compound, Mode X, Chemistry, Scattering, Excited state, Yield (chemistry), Glyoxal, General Medicine, Atomic physics, Inelastic scattering, Excitation, Beam (structure)

Abstract

Results of quantum calculations on rotationally and vibrationally inelastic scattering of 1Au(S1) trans‐glyoxal by H2,He, and Ar(E=80 meV) are presented. For scattering of 00 glyoxal and 72 glyoxal by H2, a quantitative comparison with a recent crossed beam experiment is made. The calculated cross sections for rotationally inelastic scattering are in good agreement with the experimental values, and the trend that σ(72, k=0→72, k’) falls off faster with k’ than σ(00, k=0→00, k’) is reproduced. Our calculations do not reproduce the experimental finding that, for the initial 72 level, the cross sections for the Δv7=−1 and Δv7=+1 transitions are nearly identical. The calculations on 72 glyoxal + He and Ar show important differences with 72 glyoxal + H2 in the competition of rotational excitation with vibrational excitation. Model calculations also presented here yield some interesting trends in the k’ dependence of the cross sections σ(00, k=0→x1, k’) on the vibrational mode x excited.

Published

1990

7. Consecutive Vibrational Redistribution and Predissociation Processes in s-Tetrazine–Argon Van Der Waals Complexes

Author

R. P. H. Rettschnick, H. J. Lips, J. J. F. Ramaekers, L. B. Krijnen, and J. Langelaar

Subjects

Argon, Chemistry, chemistry.chemical_element, Biochemistry, Atomic and Molecular Physics, and Optics, Out of plane, symbols.namesake, Tetrazine, chemistry.chemical_compound, symbols, Redistribution (chemistry), Supersonic speed, van der Waals force, Atomic physics, Stagnation pressure, Spectroscopy, Excitation

Abstract

s-Tetrazine argon complexes T−Arn (n = 1, 2) are formed in a supersonic expansion of argon seeded with s-tetrazine. The expansion was conducted through a nozzle of 50 or 100 μm with an argon stagnation pressure between 1 and 1.5 bar. From spectrally resolved measurements it is clear that vibrational redistribution processes as well as vibrational predissociation processes take place after SVL excitation within the complex.From rise and decay time experiments it can be concluded, that after excitation of the 6a1 complex level, the above mentioned processes are consecutive and not parallel. It appears that the out of plane mode 16a couples with the Van der Waals stretching mode. The predissociation rate of the 16a2 complex is observed to be 2.3 × 109 s−1.

Published

1983