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Few-body correlations in two-dimensional Bose and Fermi ultracold mixtures

G. Bougas, S. I. Mistakidis, P. Giannakeas, Peter Schmelcher

2021New Journal of Physics21 citationsDOIOpen Access PDF

Abstract

Abstract Few-body correlations emerging in two-dimensional harmonically trapped mixtures, are comprehensively investigated. The presence of the trap leads to the formation of atom-dimer and trap states, in addition to trimers. The Tan’s contacts of these eigenstates are studied for varying interspecies scattering lengths and mass ratio, while corresponding analytical insights are provided within the adiabatic hyperspherical formalism. The two- and three-body correlations of trimer states are substantially enhanced compared to the other eigenstates. The two-body contact of the atom-dimer and trap states features an upper bound regardless of the statistics, treated semi-classically and having an analytical prediction in the limit of large scattering lengths. Such an upper bound is absent in the three-body contact. Interestingly, by tuning the interspecies scattering length the contacts oscillate as the atom-dimer and trap states change character through the existent avoided-crossings in the energy spectra. For thermal gases, a gradual suppression of the involved two- and three-body correlations is evinced manifesting the impact of thermal effects. Moreover, spatial configurations of the distinct eigenstates ranging from localized structures to angular anisotropic patterns are captured. Our results provide valuable insights into the inherent correlation mechanisms of few-body mixtures which can be implemented in recent ultracold atom experiments and will be especially useful for probing the crossover from few- to many-atom systems.

Topics & Concepts

PhysicsUltracold atomScatteringTrimerAnisotropyDegenerate energy levelsAtom (system on chip)DimerAdiabatic processScattering lengthAtomic physicsBound stateThermalMolecular physicsQuantum mechanicsQuantumNuclear magnetic resonanceEmbedded systemComputer scienceMeteorologyCold Atom Physics and Bose-Einstein CondensatesQuantum, superfluid, helium dynamicsStrong Light-Matter Interactions