Nuclear lattice EFT calculation of 5S2 dd scattering yields scattering length 12.96 fm and effective range 3.62 fm, larger than prior results and indicating stronger repulsion.
Precise determination of lattice phase shifts and mixing angles
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abstract
We introduce a general and accurate method for determining lattice phase shifts and mixing angles, which is applicable to arbitrary, non-cubic lattices. Our method combines angular momentum projection, spherical wall boundaries and an adjustable auxiliary potential. This allows us to construct radial lattice wave functions and to determine phase shifts at arbitrary energies. For coupled partial waves, we use a complex-valued auxiliary potential that breaks time-reversal invariance. We benchmark our method using a system of two spin-1/2 particles interacting through a finite-range potential with a strong tensor component. We are able to extract phase shifts and mixing angles for all angular momenta and energies, with precision greater than that of extant methods. We discuss a wide range of applications from nuclear lattice simulations to optical lattice experiments.
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Elastic deuteron-deuteron scattering within Nuclear Lattice Effective Field Theory
Nuclear lattice EFT calculation of 5S2 dd scattering yields scattering length 12.96 fm and effective range 3.62 fm, larger than prior results and indicating stronger repulsion.