Quantum suppression of cold reactions far from the s-wave energy limit

TL;DR

This study demonstrates quantum interference suppressing a chemical reaction at millikelvin temperatures, far above the ultracold s-wave limit, revealing quantum effects in multi-partial-wave regimes.

Contribution

It provides the first experimental evidence of quantum interference suppressing reactions in the multi-partial-wave regime at higher temperatures.

Findings

Reaction rate suppressed by over an order of magnitude compared to classical predictions

Quantum interference effects observed beyond the ultracold s-wave limit

Reactions occur at temperatures where multiple partial waves contribute

Abstract

Quantum effects in chemical reactions are most pronounced at ultracold temperatures, where only a few partial waves contribute. While interference among many partial waves is theoretically expected to persist at higher temperatures, direct evidence for such quantum effects in reactive processes has been lacking. Here, we report the first observation of quantum interference suppressing a chemical reaction in the multi-partial-wave regime: resonant charge exchange between a single $^{87}$Rb atom and its parent ion $^{87}$Rb$^+$. Using quantum-logic detection on a single atom-ion pair and a calibrated in-situ measurement of Langevin collision probabilities, we benchmark the thermally averaged reaction rate against both classical and quantum predictions. We find that the reaction rate is suppressed by over an order of magnitude relative to the classical expectation, despite occurring in the millikelvin temperature regime (more than three orders of magnitude above the $s$-wave threshold), where more than a dozen partial waves contribute. These results establish quantum interference as a key mechanism in chemical reactivity beyond the ultracold limit and offer a platform for probing coherent quantum effects in atom-ion reactions where \textit{ab initio} methods remain intractable.