Searching for the Tetraneutron Resonance on the Lattice

Abstract

The nature of the tetraneutron (4n) system remains a pivotal question in nuclear physics. We investigate the 4n system using nuclear lattice effective field theory in finite volumes with a lattice size up to L=30~fm, employing both a high-precision N3LO interaction and a simplified SU(4) symmetric one. The ground-state energy is found to decrease smoothly with increasing box size, showing no plateau characteristic of a resonance. We further compute the dineutron-dineutron scattering phase shift using L\"uscher's finite-volume method. At the smallest relative momenta, the extracted 2n--2n S-wave phase shift is small, consistent with a weak interaction in the dilute limit. At intermediate momenta, it exhibits a weak attraction with a peak of approximately 10 at relative momentum of 60--84~MeV. While this structure does not constitute a resonance, the corresponding confined 4n energy of 1.7--3.3~MeV lies close to the experimentally observed low-energy peak.