Multipole-moment effects in ion-molecule reactions at low temperatures: part I -- Ion-dipole enhancement of the rate coefficients of the He$^+$ + NH$_3$ and He$^+$ + ND$_3$ reactions at collision energies near $0$ K
| Autor: | Zhelyazkova, Valentina, Martins, Fernanda B. V., Agner, Josef A., Schmutz, Hansjürg, Merkt, Frédéric |
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| Rok vydání: | 2021 |
| Předmět: | |
| Zdroj: | Phys. Chem. Chem. Phys., 2021, 23, 21606-21622 |
| Druh dokumentu: | Working Paper |
| DOI: | 10.1039/D1CP03116C |
| Popis: | The energy dependence of the rates of the reactions between He$^+$ and ammonia (NY$_3$, Y= {H,D}), forming NY$_2^+$, Y and He as well as NY$^+$, Y$_2$ and He, and the corresponding product branching ratios have been measured at low collision energies between 0 and $k_{\mathrm{B}}\cdot40$ K using a recently developed merged-beam technique [Allmendinger {\it et al.}, ChemPhysChem {\bf 17}, 3596 (2016)]. 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 was also used for adjusting the final velocity of the He Rydberg atoms, and thus the collision energy ($E_{\rm coll}$). A collision-energy resolution of about 200 mK was reached at the lowest $E_{\rm coll}$ values. The reaction rate coefficients exhibit a sharp increase at collision energies below $\sim k_{\mathrm{B}}\cdot5$ 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. The enhancement of the reaction yields of both reactions observed at the lowest collision energies is attributed to high-field-seeking states which experience linear Stark shifts at low electric fields. 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 {\it et al.} (Chem. Phys. Lett., 1985, {\bf 122}, 431) suggests that only 40\% of the close collisions are reactive. Comment: 18 pages, 8 figures |
| Databáze: | arXiv |
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