Abstract
We study the repulsive Fermi polaron in a two-component, two-dimensional system of fermionic atoms inspired by the results of a recent experiment with $^{173}$Yb atoms [N. Darkwah Oppong \textit{et al.}, Phys. Rev. Lett. \textbf{122}, 193604 (2019)]. We use the diffusion Monte Carlo method to report properties such as the polaron energy and the quasi-particle residue that have been measured in that experiment. To provide insight on the quasi-particle character of the problem, we also report results for the effective mass. We show that the effective range, together with the scattering length, is needed in order to reproduce the experimental results. Using different model potentials for the interaction between the Fermi sea and the impurity, we show that it is possible to establish a regime of universality, in terms of these two parameters, that includes the whole experimental regime. This illustrates the relevance of quantum fluctuations and beyond mean-field effects to correctly describe the Fermi polaron problem.
Highlights
We study the repulsive Fermi polaron in a two-component, two-dimensional system of fermionic atoms inspired by the results of a recent experiment with 173Yb atoms [N
Previous diffusion Monte Carlo (DMC) calculations reveal the existence of a universal regime in terms of the gas parameter nas2 for the 2D repulsive Fermi polaron, which stands for values nas2 10−3 [16], with n the particle density and as the 2D s-wave scattering length
This reflects the enhanced relevance of quantum fluctuations in a 2D Fermi polaron problem [42], which is a good testbed to study the effect of impurity-bath correlations [43]
Summary
We study the repulsive Fermi polaron in a two-component, two-dimensional system of fermionic atoms inspired by the results of a recent experiment with 173Yb atoms [N. Finite-range effects in the two-dimensional repulsive Fermi polaron We show that the effective range, together with the scattering length, is needed in order to reproduce the experimental results.
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