Nuclei with Up to A=6 Nucleons with Artificial Neural Network Wave Functions

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The ground-breaking works of Weinberg have opened the way to calculations of atomic nuclei that are based on systematically improvable Hamiltonians. Solving the associated many-body Schrodinger equation involves non-trivial difficulties, due to the non-perturbative nature and strong spin-isospin dependence of nuclear interactions. Artificial neural networks have proven to be able to compactly represent the wave functions of nuclei with up to A = 4 nucleons. In this work, we extend this approach to Li-6 and He-6 nuclei, using as input a leading-order pionless effective field theory Hamiltonian. We successfully benchmark their binding energies, point-nucleon densities, and radii with the highly-accurate hyperspherical harmonics method.

Nuclei with Up to A=6 Nucleons with Artificial Neural Network Wave Functions

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A Cavity-Microscope for Quantum Simulations with Locally-Controllable All-to-All Interactions

Higher-order moments of the elliptic flow distribution in PbPb collisions at √sNN=5.02 TeV

Bootstrapping amplitudes of scalar particles

A Cavity-Microscope for Quantum Simulations with Locally-Controllable All-to-All Interactions

Higher-order moments of the elliptic flow distribution in PbPb collisions at √sNN=5.02 TeV

Bootstrapping amplitudes of scalar particles