Add to ORKGWe investigate the asymptotic properties of higher-order binding corrections to the one-loop self-energy of excited states in atomic hydrogen. We evaluate the historically problematic A60 coefficient for all P states with principal quantum numbers n ≤ 7 and D states with n ≤ 8 and find that a satisfactory representation of the n dependence of the coefficients requires a three-parameter fit. For the high-energy contribution to A60, we find exact formulas. The results obtained are relevant for the interpretation of high-precision laser spectroscopic measurements
A high-precision numerical calculation is reported for the self-energy correction to the hyperfine s...
A first testing ground for QED in the combined presence of a strong Coulomb field and a strong magne...
Two-loop Bethe logarithms are calculated for excited P and D states in hydrogenlike systems, and est...
We present results on the self-energy correction to the energy levels of hydrogen and hydrogenlike i...
The self-energy corrections to the hyperfine splitting is evaluated for higher excited states in hyd...
A nonperturbative numerical evaluation of the one-photon electron self-energy for the 3S and 4S stat...
The fine-structure interval of P states in hydrogenlike systems can be determined theoretically with...
The radiative self-energy correction to the bound-electron g factor of 2P1/2 and 2P3/2 states in one...
We describe a nonperturbative (in Z α ) numerical evaluation of the one-photon electron self-energy ...
State-dependent quantum electrodynamic corrections are evaluated for the hyperfine splitting of nS s...
State-dependent quantum electrodynamic corrections are evaluated for the hyperfine splitting of nS s...
We present an improved calculation of higher-order corrections to the one-loop self-energy of 2P sta...
Self-energy corrections involving logarithms of the parameter Z α can often be derived within a simp...
Two-loop Bethe logarithms are calculated for excited P and D states in hydrogenlike systems, and est...
In this work, higher order QED binding corrections to the self-energy are calculated. It is our aim ...
A high-precision numerical calculation is reported for the self-energy correction to the hyperfine s...
A first testing ground for QED in the combined presence of a strong Coulomb field and a strong magne...
Two-loop Bethe logarithms are calculated for excited P and D states in hydrogenlike systems, and est...
We present results on the self-energy correction to the energy levels of hydrogen and hydrogenlike i...
The self-energy corrections to the hyperfine splitting is evaluated for higher excited states in hyd...
A nonperturbative numerical evaluation of the one-photon electron self-energy for the 3S and 4S stat...
The fine-structure interval of P states in hydrogenlike systems can be determined theoretically with...
The radiative self-energy correction to the bound-electron g factor of 2P1/2 and 2P3/2 states in one...
We describe a nonperturbative (in Z α ) numerical evaluation of the one-photon electron self-energy ...
State-dependent quantum electrodynamic corrections are evaluated for the hyperfine splitting of nS s...
State-dependent quantum electrodynamic corrections are evaluated for the hyperfine splitting of nS s...
We present an improved calculation of higher-order corrections to the one-loop self-energy of 2P sta...
Self-energy corrections involving logarithms of the parameter Z α can often be derived within a simp...
Two-loop Bethe logarithms are calculated for excited P and D states in hydrogenlike systems, and est...
In this work, higher order QED binding corrections to the self-energy are calculated. It is our aim ...
A high-precision numerical calculation is reported for the self-energy correction to the hyperfine s...
A first testing ground for QED in the combined presence of a strong Coulomb field and a strong magne...
Two-loop Bethe logarithms are calculated for excited P and D states in hydrogenlike systems, and est...