Observation of unitary p-wave interactions between fermions in an optical lattice

TL;DR

This paper reports the first observation of elastic unitary p-wave interactions between fermionic atoms in an optical lattice, demonstrating tunable interaction strengths and long pair lifetimes, advancing quantum simulation capabilities.

Contribution

It experimentally demonstrates elastic p-wave interactions in a controlled lattice environment, overcoming previous limitations due to three-body loss, and provides a framework for future quantum simulations.

Findings

Measured p-wave interaction energies near a Feshbach resonance.

Observed pair lifetimes up to fifty times longer than in free space.

Showed universal scaling of on-site interaction strengths.

Abstract

Exchange-antisymmetric pair wavefunctions in fermionic systems can give rise to unconventional superconductors and superfluids with non-trivial transport properties. The realisation of these states in controllable quantum systems, such as ultracold gases, could enable new types of quantum simulations, topological quantum gates, and exotic few-body states. However, p-wave and other antisymmetric interactions are weak in naturally occurring systems, and their enhancement via Feshbach resonances in ultracold systems has been limited by three-body loss. In this work, we create isolated pairs of spin-polarised fermionic atoms in a multi-orbital three-dimensional optical lattice. We spectroscopically measure elastic p-wave interaction energies of strongly interacting pairs of atoms near a magnetic Feshbach resonance and find pair lifetimes to be up to fifty times larger than in free space. We demonstrate that on-site interaction strengths can be widely tuned by the magnetic field and confinement strength but collapse onto a universal single-parameter curve when rescaled by the harmonic energy and length scales of a single lattice site. Since three-body processes are absent within our approach, we are able to observe elastic unitary p-wave interactions for the first time. We take the first steps towards coherent temporal control via Rabi oscillations between free-atom and interacting-pair states. All experimental observations are compared both to an exact solution for two harmonically confined atoms interacting via a p-wave pseudopotential, and to numerical solutions using an ab-initio interaction potential. The understanding and control of on-site p-wave interactions provides a necessary component for the assembly of multi-orbital lattice models, and a starting point for investigations of how to protect such a system from three-body recombination even in the presence of tunnelling.