Probing Nonlocal Spatial Correlations in Quantum Gases with Ultra-long-range Rydberg Molecules

Abstract

We present photo-excitation of ultra-long-range Rydberg molecules as a probe of spatial correlations in quantum gases. Rydberg molecules can be created with well-defined internuclear spacing, set by the radius of the outer lobe of the Rydberg electron wavefunction Rn. By varying the principal quantum number n of the target Rydberg state, the molecular excitation rate can be used to map the pair-correlation function of the trapped gas g(2)(Rn). We demonstrate this with ultracold Sr gases and probe pair-separation length scales ranging from Rn = 1400 - 3200 a0, which are on the order of the thermal de Broglie wavelength for temperatures around 1 μK. We observe bunching for a single-component Bose gas of 84Sr and anti-bunching due to Pauli exclusion at short distances for a polarized Fermi gas of 87Sr, revealing the effects of quantum statistics.