Lukas Bovermann scite author profile

We present a lattice method for determining scattering phase shifts and mixing angles for the case of an arbitrary number of coupled channels. Previous lattice studies were restricted to mixing of up to two partial waves for scattering of two spin-1/2 particles, which is insufficient for analyzing nucleon-nucleus or nucleus-nucleus scattering processes. In the proposed method, the phase shifts and mixing angles are extracted from the radial wave functions obtained by projecting the threedimensional lattice Hamiltonian onto the partial wave basis. We use a spherical wall potential as a boundary condition along with a channel-mixing auxiliary potential to construct the full-rank S-matrix. Our method can be applied to any type of particles, but we focus here on scattering of two spin-1 bosons involving up to four coupled channels. For a considered test potential, the phase shifts and mixing angles extracted on the lattice are shown to agree with the ones calculated by solving the Schrödinger equation in the continuum.

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Lattice improvement of nuclear shape calculations using unitary transformations

Bovermann¹,

Epelbaum²,

Krebs³

et al. 2022

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Wave function matching for the quantum many-body problem

Elhatisari¹,

Bovermann²,

Epelbaum³

et al. 2022

Preprint

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We introduce a new approach for solving quantum many-body systems called wave function matching. Wave function matching transforms the interaction between particles so that the wave functions at short distances match that of an easily computable interaction. This allows for calculations of systems that would otherwise be impossible due to problems such as Monte Carlo sign cancellations. We apply the method to lattice Monte Carlo simulations of light nuclei, medium-mass nuclei, neutron matter, and nuclear matter. We use interactions at next-to-next-to-next-to-leading order in the framework of chiral effective field theory and find good agreement with empirical data. These results are accompanied by new insights on the nuclear interactions that may help to resolve long-standing challenges in accurately reproducing nuclear binding energies, charge radii, and nuclear matter saturation in ab initio calculations.

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Lattice phase shifts and mixing angles for an arbitrary number of coupled channels

Bovermann

Epelbaum

Krebs

et al. 2020

SciPost Phys. Proc.

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We present a lattice method for determining scattering phase shifts and mixing angles for the case of an arbitrary number of coupled channels. The proposed method combines a spherical wall boundary condition and a channel-mixing auxiliary potential to extract the full-rank S-matrix from the radial wave functions. We consider the scattering problem of two spin-1 bosons interacting with a test potential involving up to four coupled channels. For this benchmark system, the phase shifts and mixing angles are shown to agree on the lattice and in the continuum. Our method should allow to extend previous two-channel nuclear lattice EFT simulations to mixing of more than two partial waves.

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Wave function matching for the quantum many-body problem

Elhatisari

Bovermann

Epelbaum

et al. 2023

Preprint

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show abstract

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Lukas Bovermann

Scattering phase shifts and mixing angles for an arbitrary number of coupled channels on the lattice

Lattice improvement of nuclear shape calculations using unitary transformations

Wave function matching for the quantum many-body problem

Lattice phase shifts and mixing angles for an arbitrary number of coupled channels

Wave function matching for the quantum many-body problem

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