Nonlocal nucleon-nucleus optical potentials from chiral effective field theory
ORAL
Abstract
We investigate the nonlocality in microscopic optical potentials derived from chiral effective field
theory. For this purpose we employ the Perey-Buck ansatz, which connects the energy dependence of
purely local optical potentials to a Gaussian spatial nonlocality. We find that the dominant source of
energy dependence in the microscopic real optical potential indeed arises from spatial nonlocalities,
while the energy dependence associated with the microscopic imaginary optical potential is a genuine
time nonlocality. We present results for nonlocal nucleon-nucleus optical potentials for the calcium
isotopic chain and study the dependence of the Woods-Saxon shape parameters on the isotopic
number.
theory. For this purpose we employ the Perey-Buck ansatz, which connects the energy dependence of
purely local optical potentials to a Gaussian spatial nonlocality. We find that the dominant source of
energy dependence in the microscopic real optical potential indeed arises from spatial nonlocalities,
while the energy dependence associated with the microscopic imaginary optical potential is a genuine
time nonlocality. We present results for nonlocal nucleon-nucleus optical potentials for the calcium
isotopic chain and study the dependence of the Woods-Saxon shape parameters on the isotopic
number.
–
Publication: Preprint: https://arxiv.org/abs/2509.04665
Presenters
-
Laina M Stahulak
Texas A&M University College Station
Authors
-
Laina M Stahulak
Texas A&M University College Station
-
Jeremy W Holt
Cyclotron Institute and Department of Physics and Astronomy, Texas A&M University