Application of the correlated B-spline basis functions to the leading relativistic and QED corrections of helium

Abstract

B-spline functions have been widely used in computational atomic physics. Different from the traditional B-spline basis (a simple product of two B-splines), the recently developed correlated B-spline basis functions(C-BSBF), in which the interelectronic coordinate r12 is included explicitly, have greatly improved the computational accuracy of polarizability [S. J. Yang et al., Phys. Rev. A 95, 062505 (2017)] and bethe logarithm [ S. J. Yang et al., Phys. Rev. A 100, 042509 (2019)] for singlet states of helium. Here, we report the extension of the C-BSBF to the leading relativistic and QED correction calculations for energy levels of the 1\,1S, 2\,1S, 2\,3S, and 3\,3S states of helium. The relativistic kinetic term p14, contact potential δ3(r1), δ3(r12) and Araki-Sucher correction 1/r123 are calculated by using the global operator method, in which r12n and r12n r12 involved are calculated with the generalization of Laplace's expansions. The obtained values for the ground state are δ Erel/α 2=-1.951 754 7(2) and δ EQED/α3=57.288 165(2), consistent with previous results, which opens the possibility of calculating higher-order relativistic and QED effects using the C-BSBF.