Hyperfine-to-rotational energy transfer in ultracold atom-molecule collisions

TL;DR

This study observes and analyzes hyperfine-to-rotational energy transfer in ultracold atom-molecule collisions, revealing the significant role of spin-rotation coupling and the limitations of current models.

Contribution

It provides the first direct experimental observation of hyperfine-to-rotational energy transfer in ultracold collisions and compares it with advanced quantum scattering calculations.

Findings

Observed hyperfine-to-rotational energy transfer experimentally.

Quantum calculations deviate from observations, indicating missing physics.

Spin-rotation coupling is enhanced near conical intersections.

Abstract

Energy transfer between different mechanical degrees of freedom in atom-molecule collisions has been widely studied and largely understood. However, systems involving spins remain less explored, especially with a state-to-state precision. Here, we directly observed the energy transfer from atomic hyperfine to molecular rotation in the $^{87}$Rb ($|F_a,M_{F_a}\rangle = |2,2\rangle$) + $^{40}$K$^{87}$Rb (in the rovibronic ground state $N=0$) $\longrightarrow$ Rb ($ |1,1\rangle$) + KRb ($N=0,1,2$) exothermic collision. We probed the quantum states of the collision products using resonance-enhanced multi-photon ionization followed by time-of-flight mass spectrometry. We also carried out state-of-the-art quantum scattering calculations, which rigorously take into account the coupling between the spin and rotational degrees of freedom at short range, and assume that the KRb monomer can be treated as a rigid rotor moving on a single potential energy surface. The calculated product rotational state distribution deviates from the observations even after extensive tuning of the atom-molecule potential energy surface, suggesting that vibrational degrees of freedom and conical intersections play an important part in ultracold Rb + KRb collisions. Additionally, our ab initio calculations indicate that spin-rotation coupling is dramatically enhanced near a conical intersection, which is energetically accessible at short range. The observations confirm that spin is coupled to mechanical rotation at short range and establish a benchmark for future theoretical studies.