Abstract
While ab initio many-body techniques have been able to successfully describe the properties of light and intermediate mass nuclei based on chiral effective field theory interactions, neutron-rich nuclei still remain out of reach for these methods. Conversely, energy density functional approaches can be used to calculate properties of heavy nuclei but rely mostly on phenomenological interactions. A usable form of the nuclear energy density functional that is rooted in the modern theory of nuclear forces was presented recently. The first component of this new set of functionals corresponds to the direct part (Hartree term) of the expectation value of local chiral potentials on a Slater determinant. The exchange term, which is a functional of the non-local density, is transformed into a local functional by applying the density matrix expansion. In order to reduce the computational cost due to the direct implementation of non-separable, local interactions in the Hartree term, we use an approximation to represent the regularized Yukawa functions in terms of a sum of (separable) Gaussian functions. These proceedings analyze the accuracy of such an approximation in terms of the number of Gaussian functions and look for an optimal value that gives an acceptable level of accuracy while maintaining the computational memory requirements in a many-body calculation as low as possible.
Highlights
One of the overarching goals of nuclear physics is to find a theory capable of describing nuclear structure and reactions in terms of the underlying interactions between quarks and gluons
Following earlier studies [11], we have recently proposed a new method to determine an Energy Density Functional (EDF) from microscopic nuclear potentials derived from χ-EFT through a tool known as the Density Matrix Expansion (DME)
The implementation of microscopically-constrained EDF allows performing many-body calculations of large neutron-rich systems with a systematic order-by-order improvement determined by χ-EFT
Summary
One of the overarching goals of nuclear physics is to find a theory capable of describing nuclear structure and reactions in terms of the underlying interactions between quarks and gluons. In contrast to ab initio methods, Energy Density Functional (EDF) methods, known as self-consistent mean-field approaches, substitute the interaction due to all pairs of nucleons by an “average” of the interaction with all the other nucleons [9, 10] This substitution significantly reduces the computational cost of many-body nuclear calculations and allows estimating properties of heavy systems such as the neutron-rich nuclei mentioned earlier. The procedure briefly outlined above results in a semi-phenomenological approach in which the re-parametrization of the Skyrme-like part encodes the zero-range, i.e., high-energy, part of the chiral potential and represents the short-range interaction, while the finite-range part of the interaction provides the order-by-order improvement to the description of many-body potentials With this approach it is in principle possible to construct a scalable framework capable of describing neutron-rich nuclei with a series of systematic improvements
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