R.G. Haire scite author profile

The atomic level structure of the element fermium was investigated for the first time using a sample of 2.7x10(10) atoms of the isotope 255Fm with a half-life of 20.1 h. The atoms were evaporated from a filament and stored in the argon buffer gas of an optical cell. Atomic levels were sought by the method of resonance ionization spectroscopy using an excimer-dye-laser combination. Two atomic levels were found at wave numbers (25 099.8+/-0.2) and (25 111.8+/-0.2) cm(-1). Partial transition rates to the 5f(12)7s(2) (3)H(e)(6) ground state have been determined from their saturation characteristics. Multiconfiguration Dirac-Fock calculations suggest that the leading orders of these levels could be the 5f(12)7s7p (5)I(o)(6) and 5f(12)7s7p (5)G(o)(5) terms.

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On the electronic configuration in Pu: spectroscopy and theory

Tobin

Söderlind

Landa

et al. 2008

J. Phys.: Condens. Matter

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Photoelectron spectroscopy, synchrotron-radiation-based x-ray absorption, electron energy loss spectroscopy, and density-functional calculations within the mixed-level and magnetic models, together with canonical band theory, have been used to study the electron configuration in Pu. These methods suggest a 5f n occupation for Pu of 5 n < 6, with n = 6, contrary to what has recently been suggested in several publications. We show that the n = 6 picture is inconsistent with the usual interpretation of photoemission, x-ray absorption, and electron energy loss spectra. Instead, these spectra support the traditional conjecture of a 5f 5 occupation in Pu as is obtained by density-functional theory. We further argue, based on 5f-band filling, that an n = 6 hypothesis is incompatible with the position of Pu in the actinide series and its monoclinic ground-state phase.

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Rampant changes in5f5∕2and5f7∕2filling across

et al. 2007

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Resonance ionization spectroscopy of fermium (Z=100)

Sewtz

Backe

Dong

et al. 2003

Spectrochimica Acta Part B: Atomic Spectroscopy

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R.G. Haire

Emergence of Strong Exchange Interaction in the Actinide Series: The Driving Force for Magnetic Stabilization of Curium

First Observation of Atomic Levels for the Element Fermium (Z=100)

On the electronic configuration in Pu: spectroscopy and theory

Rampant changes in5f5∕2and5f7∕2filling across

Resonance ionization spectroscopy of fermium (Z=100)

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