Observation of quantum capture in an ion-molecule reaction

TL;DR

This study experimentally confirms quantum effects increasing ion-molecule reaction rates at ultracold temperatures, validating a 1954 prediction and revealing quantum enhancement in reactions without dipole or quadrupole moments.

Contribution

First experimental observation of quantum capture enhancement in ion-molecule reactions at ultracold temperatures, confirming a long-standing theoretical prediction.

Findings

Reaction rate increases at low collision energies due to quantum effects.

Quantum enhancement observed in reactions without dipole or quadrupole moments.

Supporting measurements with HD$^+$ and HD reinforce the findings.

Abstract

In 1954, Vogt and Wannier (Phys. Rev. 95, 1190) predicted that the capture rate of a polarizable neutral atom or molecule by an ion should increase by a factor of two compared to the classical Langevin rate as the collision energy approaches zero. This prediction has not been verified experimentally. The H$_2^+$ + H$_2$ reaction is ideally suited to observe this effect, because the small reduced mass makes quantum effects related to s-wave scattering observable at higher collision energies than in other systems. Moreover, the reaction rate for this barrierless, strongly exothermic reaction follows the classical Langevin capture model down to cold-collision conditions (about $k_\mathrm{B} \cdot~1\,\mathrm{K}$) and is not affected by short-range interactions. Below this temperature, a strong enhancement of the reaction rate resulting from charge--quadrupole interaction between H$_2^+$ and ground-state ortho H$_2$ ($J=1$) was observed. Here we present an experimental study of the reaction of H$_2^+$ and para H$_2$ ($J=0$), which has no dipole and no quadrupole moments, at collision energies below $k_\mathrm{B}\cdot 1\,\mathrm{K}$. We observe an enhancement at the lowest collision energies which is attributed to the quantum enhancement predicted by Vogt and Wannier. Measurements of the reaction of HD$^+$ with HD support this conclusion.