Quantum Electrodynamics of Heavy Ions and Atoms

The precision calculations of the isotope shifts of the $n = 1$, $n = 2$ energy levels and the corresponding transition energies in helium-like highly charged ions are performed. The total isotope shift is mainly determined by a sum of the field and mass shifts. The field shift is calculated by the configuration-interaction Dirac-Fock-Sturm method. The quantum electrodynamics corrections to this contribution are taken into account approximately by using the corresponding one-electron formulas. The calculation of the mass shift is performed within the framework of the Breit approximation and includes the quantum electrodynamics contributions, which become very significant for heavy ions. For the thorium and uranium ions the nuclear polarization and deformation corrections are taken into account.

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Quantum Electrodynamics Effects in Heavy Ions and Atoms

10.1063/1.3585806 ◽

2011 ◽

Cited By ~ 5

Author(s):

V. M. Shabaev ◽

O. V. Andreev ◽

A. I. Bondarev ◽

D. A. Glazov ◽

Y. S. Kozhedub ◽

...

Keyword(s):

Quantum Electrodynamics ◽

Heavy Ions

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Specimen Preparation of Near Surface Ion Irradiated Samples

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100117820 ◽

1985 ◽

Vol 43 ◽

pp. 170-171

Author(s):

K. F. Russell ◽

L. L. Horton

Keyword(s):

Radiation Damage ◽

Heavy Ions ◽

Target Material ◽

Metal Alloys ◽

Specimen Surface ◽

Specimen Preparation ◽

Particle Accelerators ◽

Near Surface ◽

Graaff Accelerator ◽

Van De Graaff

Beams of heavy ions from particle accelerators are used to produce radiation damage in metal alloys. The damaged layer extends several microns below the surface of the specimen with the maximum damage and depth dependent upon the energy of the ions, type of ions, and target material. Using 4 MeV heavy ions from a Van de Graaff accelerator causes peak damage approximately 1 μm below the specimen surface. To study this area, it is necessary to remove a thickness of approximately 1 μm of damaged metal from the surface (referred to as “sectioning“) and to electropolish this region to electron transparency from the unirradiated surface (referred to as “backthinning“). We have developed electropolishing techniques to obtain electron transparent regions at any depth below the surface of a standard TEM disk. These techniques may be applied wherever TEM information is needed at a specific subsurface position.

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