0000000000021302

AUTHOR

Larry A. Viehland

showing 3 related works from this author

Exploiting transport properties for the detection of optical pumping in heavy ions

2020

We present a kinetic model for optical pumping in Lu$^+$ and Lr$^+$ ions as well as a theoretical approach to calculate the transport properties of Lu$^+$ in its ground $^1S_0$ and metastable $^3D_1$ states in helium background gas. Calculations of the initial ion state populations, the field and temperature dependence of the mobilities and diffusion coefficients, and the ion arrival time distributions demonstrate that the ground- and metastable-state ions can be collected and discriminated efficiently under realistic macroscopic conditions.

PhysicsKinetic modelAtomic Physics (physics.atom-ph)FOS: Physical scienceschemistry.chemical_elementSuperheavy Elements01 natural sciencesLutetiumPhysics - Atomic Physics010305 fluids & plasmasIonOptical pumpingchemistry0103 physical sciencesddc:530Atomic physics010306 general physicsLawrenciumPhysical Review A
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Mobility of the Singly-Charged Lanthanide and Actinide Cations: Trends and Perspectives

2020

The current status of gaseous transport studies of the singly-charged lanthanide and actinide ions is reviewed in light of potential applications to superheavy ions. The measurements and calculations for the mobility of lanthanide ions in He and Ar agree well, and they are remarkably sensitive to the electronic configuration of the ion, namely, whether the outer electronic shells are 6s, 5d6s or 6s$^2$. The previous theoretical work is extended here to ions of the actinide family with zero electron orbital momentum: Ac$^+$ (7s$^2$, $^1$S), Am$^+$ (5f$^7$7s $^9$S$^\circ$), Cm$^+$ (5f$^7$7s$^2$ $^8$S$^\circ$), No$^+$ (5f$^{14}$7s $^2$S) and Lr$^+$ (5f$^{14}$7s$^2$ $^1$S). The calculations rev…

LanthanideAtomic Physics (physics.atom-ph)Ab initioFOS: Physical sciences02 engineering and technologyElectroninteraction potential010402 general chemistry7. Clean energy01 natural sciencesPhysics - Atomic PhysicsIonlcsh:Chemistryion mobilityAtomlanthanideselectronic configurationOriginal ResearchPhysicsIonic radiussuperheavy ionsactinidesGeneral ChemistryActinide021001 nanoscience & nanotechnology3. Good health0104 chemical sciencesChemistrylcsh:QD1-999ddc:540Electron configurationAtomic physics0210 nano-technology
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Laser Resonance Chromatography of Superheavy Elements.

2020

Optical spectroscopy constitutes the historical path to accumulate basic knowledge on the atom and its structure. Former work based on fluorescence and resonance ionization spectroscopy enabled identifying optical spectral lines up to element 102, nobelium. The new challenges faced in this research field are the refractory nature of the heavier elements and the decreasing production yields. A new concept of ion-mobility-assisted laser spectroscopy is proposed to overcome the sensitivity limits of atomic structure investigations persisting in the region of the superheavy elements. The concept offers capabilities of both broadband-level searches and high-resolution hyperfine spectroscopy of s…

PhysicsField (physics)Atomic Physics (physics.atom-ph)General Physics and Astronomychemistry.chemical_elementFOS: Physical sciencesSuperheavy ElementsSynthetic element7. Clean energy01 natural sciencesSpectral line3. Good healthPhysics - Atomic Physicschemistry0103 physical sciencesddc:530NobeliumAtomic physics010306 general physicsSpectroscopyHyperfine structureRefractory (planetary science)Physical review letters
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