Multipole-moment Effects in Ion-molecule Reactions at Low Temperatures: Part I - Ion-dipole Enhancement of the Rate Coefficients of the He + NH and He + ND Reactions at Collisional Energies / Near 0 K

Overview

Journal Phys Chem Chem Phys

Publisher Royal Society of Chemistry

Specialties Biophysics
Chemistry

Date 2021 Sep 27

PMID 34569565

Citations 4

Authors

Valentina Zhelyazkova

Fernanda B V Martins

Josef A Agner

Hansjurg Schmutz

Frederic Merkt

Affiliations

Soon will be listed here.

Abstract

The energy dependence of the rates of the reactions between He and ammonia (NY, Y = {H,D}), forming NY, Y and He as well as NY, Y and He, and the corresponding product branching ratios have been measured at low collision energies between 0 and ·40 K using a recently developed merged-beam technique [Allmendinger , , 2016, , 3596]. To avoid heating of the ions by stray electric fields, the reactions are observed within the large orbit of a highly excited Rydberg electron. A beam of He Rydberg atoms was merged with a supersonic beam of ammonia using a curved surface-electrode Rydberg-Stark deflector, which is also used for adjusting the final velocity of the He Rydberg atoms, and thus the collision energy. A collision-energy resolution of about 200 mK was reached at the lowest values. The reaction rate coefficients exhibit a sharp increase at collision energies below ∼·5 K and pronounced deviations from Langevin-capture behaviour. The experimental results are interpreted in terms of an adiabatic capture model describing the rotational-state-dependent orientation of the ammonia molecules by the electric field of the He atom. The model faithfully describes the experimental observations and enables the identification of three classes of |〉 rotational states of the ammonia molecules showing different low-energy capture behaviour: (A) high-field-seeking states with || ≥ 1 correlating to the lower component of the umbrella-motion tunnelling doublet at low fields. These states undergo a negative linear Stark shift, which leads to strongly enhanced rate coefficients; (B) high-field-seeking states subject to a quadratic Stark shift at low fields and which exhibit only weak rate enhancements; and (C) low-field-seeking states with || ≥ 1. These states exhibit a positive Stark shift at low fields, which completely suppresses the reactions at low collision energies. Marked differences in the low-energy reactivity of NH and ND-the rate enhancements in ND are more pronounced than in NH-are quantitatively explained by the model. They result from the reduced magnitudes of the tunnelling splitting and rotational intervals in ND and the different occupations of the rotational levels in the supersonic beam caused by the different nuclear-spin statistical weights. Thermal capture rate constants are derived from the model for the temperature range between 0 and 10 K relevant for astrochemistry. Comparison of the calculated thermal capture rate coefficients with the absolute reaction rates measured above 27 K by Marquette (, 1985, , 431) suggests that only 40% of the close collisions are reactive.

Citing Articles

Cold reactions of He with OCS and CO: competitive kinetics and the effects of the molecular multipole moments.

Martins F, Zhelyazkova V, Merkt F Phys Chem Chem Phys. 2024; 26(38):24799-24808.

PMID: 39297210 PMC: 11413858. DOI: 10.1039/d4cp02871f.

Reaction of an Ion and a Free Radical near 0 K: He + NO → He + N + O.

Zhelyazkova V, Martins F, Schilling S, Merkt F J Phys Chem A. 2023; 127(6):1458-1468.

PMID: 36752385 PMC: 9940198. DOI: 10.1021/acs.jpca.2c08221.

Multipole-moment effects in ion-molecule reactions at low temperatures: part III - the He + CH and He + CD reactions at low collision energies and the effect of the charge-octupole interaction.

Zhelyazkova V, Martins F, Merkt F Phys Chem Chem Phys. 2022; 24(26):16360-16373.

PMID: 35762649 PMC: 9258730. DOI: 10.1039/d1cp05861d.

Multipole-moment effects in ion-molecule reactions at low temperatures: part II - charge-quadrupole-interaction-induced suppression of the He + N reaction at collision energies below ·10 K.

Zhelyazkova V, Martins F, Zesko M, Merkt F Phys Chem Chem Phys. 2022; 24(5):2843-2858.

PMID: 35050290 PMC: 8809083. DOI: 10.1039/d1cp04798a.

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