Quantum mechanical and quasiclassical calculations for the H+D2→HD+D reaction: Reaction probabilities and differential cross sections

The time-delayed forward scattering mechanism recently identified by Althorpe et al. [Nature (London) 416, 67 (2002)] for the H+D2(v=0,j=0)→HD(v′=3,j′=0)+D reaction was analyzed by using quasiclassical trajectory (QCT) methodology. The QCT results were found to match the quantum wavepacket snapshots of Althorpe et al., albeit without the quantum scattering effects. Trajectories were analyzed on the fly to investigate the dynamics of the atoms during the reaction. The dominant reaction mechanism progresses from hard collinear impacts, leading to direct recoil, toward glancing impacts. The increased time required for forward scattered trajectories is due to the rotation of the transient HDD complex. Forward scattered trajectories display symmetric stretch vibrations of the transient HDD complex, a signature of the presence of a resonance, or a quantum bottleneck state.

Section: 10supporting

confidence: 62%

A quasiclassical trajectory study of the time-delayed forward scattering in the hydrogen exchange reaction

Greaves

Murdock

Wrede

2008

“…In principle, the QCT calculations already employed at lower collision energies with reasonable success to predict integral 25-34 and differential cross sections 28,30,35,36 should become more accurate. As the collision energy is increased, the effects of zeropoint energy and nonclassical behavior generally become less prominent.…”

Section: Introductionmentioning

confidence: 99%

Differential cross sections for H+D2→HD(v′=1, J′=1,5,8)+D at 1.7 eV

Fernández-Alonso

Bean

Zare

1999

Differential cross section polarization moments: Location of the D-atom transfer in the transition-state region for the reactions Cl+C 2 D 6 →DCl (v ′ =0,J ′ =1)+ C 2 D 5 and Cl+CD 4 →DCl (v ′ =0,J ′ =1)+ CD 3 A 1:4 mixture of HBr and D 2 is expanded into a vacuum chamber, fast H atoms are generated by photolysis of HBr ca. 210 nm, and the resulting HD (vЈ, JЈ) products are detected by (2ϩ1) resonance-enhanced multiphoton ionization ͑REMPI͒ in a Wiley-McLaren time-of-flight spectrometer. The photoloc technique allows a direct inversion of HD (vЈ, JЈ) core-extracted time-of-flight profiles into differential cross sections for the HϩD 2 →HD(vЈϭ1, JЈϭ1,5,8)ϩD reactions at collision energies ca. 1.7 eV. The data reveal a systematic trend from narrow, completely backward scattering for HD (vЈϭ1, JЈϭ1) toward broader, side scattering for HD (vЈϭ1, JЈϭ8). A calculation based on the line of centers model with nearly elastic specular scattering accounts qualitatively for the observations.

“…Although QCT cannot accurately reproduce experiments in as much detail as QM, it has been used for a wide number of studies of the hydrogen exchange reaction and has shown surprisingly good agreement with experimental and quantum mechanical cross sections. [14][15][16] However, QCT can nevertheless give valuable insight into the mechanisms leading to reaction. 17 This has been used to investigate short-lived collision complexes ͑in terms of time delay͒ 18,19 and for general investigation of the hydrogen exchange reaction.…”

Section: Introductionmentioning

confidence: 99%

New, unexpected, and dominant mechanisms in the hydrogen exchange reaction

Greaves

Murdock

Wrede

et al. 2008

A quasiclassical trajectory study of the state specific H+D2(υ=0,j=0)→HD(υ′=0,j′=0)+D reaction at a collision energy of 1.85eV (total energy of 2.04eV) found that the scattering is governed by two unexpected and dominant new mechanisms, and not by direct recoil as is generally assumed. The new mechanisms involve strong interaction with the sloping potential around the conical intersection, an area of the potential energy surface not previously considered to have much effect upon reactive scattering. Initial investigations indicate that more than 50% of reactive scattering could be the result of these new mechanisms at this collision energy. Features in the corresponding quantum mechanical results can be attributed to these new (classical) reaction mechanisms.