Abstract
We consider the problem of including varLambda hyperons into the ab initio framework of nuclear lattice effective field theory. In order to avoid large sign oscillations in Monte Carlo simulations, we make use of the fact that the number of hyperons is typically small compared to the number of nucleons in the hypernuclei of interest. This allows us to use the impurity lattice Monte Carlo method, where the minority species of fermions in the full nuclear Hamiltonian is integrated out and treated as a worldline in Euclidean projection time. The majority fermions (nucleons) are treated as explicit degrees of freedom, with their mutual interactions described by auxiliary fields. This is the first application of the impurity lattice Monte Carlo method to systems where the majority particles are interacting. Here, we show how the impurity Monte Carlo method can be applied to compute the binding energies of the light hypernuclei. In this exploratory work we use spin-independent nucleon–nucleon and hyperon–nucleon interactions to test the computational power of the method. We find that the computational effort scales approximately linearly in the number of nucleons. The results are very promising for future studies of larger hypernuclear systems using chiral effective field theory and realistic hyperon–nucleon interactions, as well as applications to other quantum many-body systems.
Highlights
Hypernuclei are bound states of one or two hyperons together with a core composed of nucleons
We focus on the Monte Carlo calculation of the binding energy of light hypernuclei, by means of a simplified Y N interaction, consisting of a single contact interaction, tuned to a best description of the the empirical binding energies of the s-shell hypernuclei with A = 3, 4, 5.2 For the N N interaction, we use a simple leading order interaction similar to that described in Ref. [18]
We develop the impurity lattice Monte Carlo (ILMC) formalism following Ref. [16], who considered a system of spin-up and spin-down fermions, with a contact interaction which operates between fermions of opposite spin
Summary
Hypernuclei are bound states of one or two hyperons together with a core composed of nucleons. Due to the scarcity of direct hyperon–nucleon (Y N ) and hyperon–hyperon (Y Y ) scattering data, these unusual forms of baryonic matter play an important role in pinning down the fundamental baryon–baryon forces This requires on the one hand an effective field theory (EFT) description of the underlying forces, as pioneered in Refs. The physics of hypernuclei requires a different approach, and in this paper we show how the computational problems are solved using the impurity lattice Monte Carlo (ILMC) method. The spatial position of this worldline is updated using Monte Carlo updates, while the interactions between the majority fermions are described by the auxiliary field formalism [4]. 5, we discuss the Monte Carlo updating of the hyperon worldline and the auxiliary fields, which encode the interactions between nucleons.
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