Transformation of bound states of relativistic hydrogen-l ike atom into two-component form

Abstract

A single-step Eriksen transformation of~1S1/2,~2P1/2 and~2P3/2 states of the relativistic hydrogen-like atom is performed exactly by expressing each transformed function (TF) as a linear combination of eigenstates of the Dirac Hamiltonian. The transformed functions, which are four-component spinors with vanishing two lower components, are calculated numerically and have the same symmetries as the initial states. For all nuclear charges~Z ∈ [1… 92] a contribution of the initial state to TFs exceeds 86\% of the total probability density. Next large contribution to TFs comes from continuum states with negative energies close to~-m0c2-Eb, where~Eb is the binding energy of initial state. Contribution of other states to TFs is less than~0.1\% of the total probability density. Other components of TFs are nearly zero which confirms both validity of the Eriksen transformation and accuracy of the numerical calculations. The TFs of~1S1/2 and~2P1/2 states are close to~1s and~2p states of the nonrelativistic hydrogen-like atom, respectively, but the TF of~2P3/2 state differs qualitatively from the~2p state. Functions calculated with use of a linearized Eriksen transformation, being equivalent to the second order Foldy-Wouthuysen transformation, are compared with corresponding functions obtained by Eriksen transformation. A very good agreement between both results is obtained.