We present two complementary methods to calculate the Andreev bound state energies of a single-level quantum dot connected to superconducting leads. The first method is based on a mapping to a low-energy model and can extract the energies from quantum Monte Carlo data. The second method maps the full model to an exactly solvable atomic limit, providing a fast and reliable way to explore the parameter space.
We present two complementary methods to calculate the Andreev bound state energies of a single-level quan-tum dot connected to superconducting leads described by the superconducting impurity Anderson model. The first method, which is based on a mapping to a low-energy model, can be utilized to extract the Andreev bound state energies from finite-temperature, imaginary-time quantum Monte Carlo data without the necessity of any analytic continuation technique. The second method maps the full model on an exactly solvable superconducting atomic limit with renormalized parameters. As such, it represents a fast and reliable method for a quick scan of the parameter space. We demonstrate that after adding a simple band correction this method can provide predictions for measurable quantities, including the Josephson current, that are in a solid quantitative agreement with precise results obtained by the numerical renormalization group and quantum Monte Carlo.
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