Rotational Excitation of HD by Hydrogen Revisited

Desrousseaux, Benjamin; Coppola, Carla Maria; Kazandjian, M. V.; Lique, François

doi:10.1021/acs.jpca.8b08618

Cited by 16 publications

(16 citation statements)

References 45 publications

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“…Therefore, it is crucial to investigate the chemical reactions involving HD, especially with neutral and ionised atoms, in order to characterise the cooling dynamics. If the reaction with the most abundant species H has been widely studied (see for instance (Flower & Roueff 1999;Ely et al 2016;Desrousseaux et al 2018)), very little is known about its ionic counterpart H + + HD, which is the subject of the present article.…”

Section: Introductionmentioning

confidence: 99%

Quantum mechanical study of the high-temperature H+ + HD → D+ + H2 reaction for the primordial universe chemistry

Lepers

Guillon

Honvault

2019

Monthly Notices of the Royal Astronomical Society

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We use the time-independent quantum-mechanical formulation of reactive collisions in order to investigate the state-to-state H + + HD → D + + H 2 chemical reaction. We compute cross sections for collision energies up to 1.8 electron-volts and rate coefficients for temperatures up to 10000 kelvin. We consider HD in the lowest vibrational level v = 0 and rotational levels j = 0 to 4, and H 2 in vibrational levels v ′ = 0 to 3 and rotational levels j ′ = 0 to 9. For temperatures below 4000 kelvin, the rate coefficients strongly vary with the initial rotational level j, depending on whether the reaction is endothermic ( j ≤ 2) or exothermic ( j ≥ 3). The reaction is also found less and less probable as the final vibrational quantum number v ′ increases. Our results illustrate the importance of studying state-to-state reactions, in the context of the chemistry of the primordial universe.

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Section: Introductionmentioning

confidence: 99%

Quantum mechanical study of the high-temperature H+ + HD → D+ + H2 reaction for the primordial universe chemistry

Lepers

Guillon

Honvault

2019

Monthly Notices of the Royal Astronomical Society

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“…Hence, since the Hamiltonian is symmetric with respect to interchange of the two hydrogens, there will be no coupling between odd (ortho) and even (para) rotational states of H 2 , so that the number of coupled channels is reduced. We then obtained inelastic, reactive and exchange integral cross sections following the approach described by Tao and Alexander 43 and recently used to study the rotational excitation of several hydrides in collision with H [44][45][46][47] . Excited vibrational states up to v = 17 and up to j = 6 (E max = 4.4 eV) are included in the basis to ensure convergence of the cross sections.…”

Section: Close Coupling (Cc) Calculationsmentioning

confidence: 99%

HD–H⁺ collisions: statistical and quantum state-to-state studies

Desrousseaux

Konings

Loreau

et al. 2021

Phys. Chem. Chem. Phys.

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“…This was confirmed by subsequent theoretical studies which revealed that the angular distribution of the scattered HD in collisions with H 2 was dominated by a single (l = 2) partial-wave shape resonance as around 1 K 19 . Collisions of HD with H 2 are also of current astrophysical interest as the HD molecule is believed to have played an important role in the cooling of the primordial gas in the formation of the first stars and galaxies [20][21][22] .…”

Section: Introductionmentioning

confidence: 99%

Controlling rotational quenching rates in cold molecular collisions

Croft

Balakrishnan

2019

The Journal of Chemical Physics

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The relative orientation of colliding molecules plays a key role in determining the rates of chemical processes. Here we examine in detail a prototypical example: rotational quenching of HD in cold collisions with H 2 . We show that the rotational quenching rate from j = 2 → 0, in the v = 1 vibrational level, can be maximized by aligning the HD along the collision axis and can be minimized by aligning the HD at the so called magic angle. This follows from quite general helicity considerations and suggests that quenching rates for other similar systems can also be controlled in this manner.

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Rotational Excitation of HD by Hydrogen Revisited

Cited by 16 publications

References 45 publications

Quantum mechanical study of the high-temperature H+ + HD → D+ + H2 reaction for the primordial universe chemistry

Quantum mechanical study of the high-temperature H+ + HD → D+ + H2 reaction for the primordial universe chemistry

HD–H⁺ collisions: statistical and quantum state-to-state studies

Controlling rotational quenching rates in cold molecular collisions

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Rotational Excitation of HD by Hydrogen Revisited

Cited by 16 publications

References 45 publications

Quantum mechanical study of the high-temperature H+ + HD → D+ + H2 reaction for the primordial universe chemistry

Quantum mechanical study of the high-temperature H+ + HD → D+ + H2 reaction for the primordial universe chemistry

HD–H+ collisions: statistical and quantum state-to-state studies

Controlling rotational quenching rates in cold molecular collisions

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Product

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HD–H⁺ collisions: statistical and quantum state-to-state studies