Abstract
We present a determination of nucleon-nucleon scattering phase shifts for l >= 0. The S, P, D and F phase shifts for both the spin-triplet and spin-singlet channels are computed with lattice Quantum ChromoDynamics. For l > 0, this is the first lattice QCD calculation using the Luscher finite-volume formalism. This required the design and implementation of novel lattice methods involving displaced sources and momentum-space cubic sinks. To demonstrate the utility of our approach, the calculations were performed in the SU(3)-flavor limit where the light quark masses have been tuned to the physical strange quark mass, corresponding to m_pi = m_K ~ 800 MeV. In this work, we have assumed that only the lowest partial waves contribute to each channel, ignoring the unphysical partial wave mixing that arises within the finite-volume formalism. This assumption is only valid for sufficiently low energies; we present evidence that it holds for our study using two different channels. Two spatial volumes of V ~ (3.5 fm)^3 and V ~ (4.6 fm)^3 were used. The finite-volume spectrum is extracted from the exponential falloff of the correlation functions. Said spectrum is mapped onto the infinite volume phase shifts using the generalization of the Luscher formalism for two-nucleon systems.
Highlights
Understanding low-energy nuclear physics directly from the underlying theory of strong interactions, Quantum ChromoDynamics (QCD), remains a primary goal of nuclear physicists
We have assumed that only the lowest partial waves contribute to each channel, ignoring the unphysical partial wave mixing that arises within the finite-volume formalism
Assuming the results are within the range of convergence of the effective range expansion (ERE), the infinite volume bound state energies may be determined by solving for poles in the derived scattering amplitude
Summary
Understanding low-energy nuclear physics directly from the underlying theory of strong interactions, Quantum ChromoDynamics (QCD), remains a primary goal of nuclear physicists. A recent, exciting development is the use of lattice field theory to regularize the two- and three-nucleon EFT and predict properties of light nuclei, such as the recent computation of the Hoyle State [12] All of these impressive theoretical applications rely upon experimental input of the nuclear interactions. Tremendous progress has been made in performing LQCD calculations of two-meson interactions [28,29,30,31,32,33,34,35,36] These calculations use the Luscher formalism [37,38,39,40,41,42,43,44,45] to relate energy levels in a finite periodic volume to the infinite volume scattering phase shifts. This work is an extension of a previous determination of the NN S-wave interactions [53] on the same LQCD gauge configurations
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