Electronic ground states of Fe 2 + and Co 2 + as determined by x-ray absorption and x-ray magnetic circular dichroism spectroscopy

V. Zamudio-Bayer; K. Hirsch; A. Langenberg; A. Lawicki; A. Terasaki; B. V. Issendorff; J. T. Lau

doi:10.1063/1.4939078

Electronic ground states of Fe 2 + and Co 2 + as determined by x-ray absorption and x-ray magnetic circular dichroism spectroscopy

V. Zamudio-Bayer, K. Hirsch, A. Langenberg, A. Lawicki, A. Terasaki, B. V. Issendorff, J. T. Lau

Physical Chemistry

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16 Citations (Scopus)

Abstract

The ⁶Π electronic ground state of the Co 2 + diatomic molecular cation has been assigned experimentally by x-ray absorption and x-ray magnetic circular dichroism spectroscopy in a cryogenic ion trap. Three candidates, ⁶Φ, ⁸Φ, and ⁸Γ, for the electronic ground state of Fe 2 + have been identified. These states carry sizable orbital angular momenta that disagree with theoretical predictions from multireference configuration interaction and density functional theory. Our results show that the ground states of neutral and cationic diatomic molecules of 3d transition elements cannot generally be assumed to be connected by a one-electron process.

Original language	English
Article number	244318
Journal	Journal of Chemical Physics
Volume	143
Issue number	24
DOIs	https://doi.org/10.1063/1.4939078
Publication status	Published - Dec 28 2015

All Science Journal Classification (ASJC) codes

Physics and Astronomy(all)
Physical and Theoretical Chemistry

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title = "Electronic ground states of Fe 2 + and Co 2 + as determined by x-ray absorption and x-ray magnetic circular dichroism spectroscopy",

abstract = "The 6Π electronic ground state of the Co 2 + diatomic molecular cation has been assigned experimentally by x-ray absorption and x-ray magnetic circular dichroism spectroscopy in a cryogenic ion trap. Three candidates, 6Φ, 8Φ, and 8Γ, for the electronic ground state of Fe 2 + have been identified. These states carry sizable orbital angular momenta that disagree with theoretical predictions from multireference configuration interaction and density functional theory. Our results show that the ground states of neutral and cationic diatomic molecules of 3d transition elements cannot generally be assumed to be connected by a one-electron process.",

author = "V. Zamudio-Bayer and K. Hirsch and A. Langenberg and A. Lawicki and A. Terasaki and Issendorff, {B. V.} and Lau, {J. T.}",

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T1 - Electronic ground states of Fe 2 + and Co 2 + as determined by x-ray absorption and x-ray magnetic circular dichroism spectroscopy

AU - Zamudio-Bayer, V.

AU - Hirsch, K.

AU - Langenberg, A.

AU - Lawicki, A.

AU - Terasaki, A.

AU - Issendorff, B. V.

AU - Lau, J. T.

PY - 2015/12/28

Y1 - 2015/12/28

N2 - The 6Π electronic ground state of the Co 2 + diatomic molecular cation has been assigned experimentally by x-ray absorption and x-ray magnetic circular dichroism spectroscopy in a cryogenic ion trap. Three candidates, 6Φ, 8Φ, and 8Γ, for the electronic ground state of Fe 2 + have been identified. These states carry sizable orbital angular momenta that disagree with theoretical predictions from multireference configuration interaction and density functional theory. Our results show that the ground states of neutral and cationic diatomic molecules of 3d transition elements cannot generally be assumed to be connected by a one-electron process.

AB - The 6Π electronic ground state of the Co 2 + diatomic molecular cation has been assigned experimentally by x-ray absorption and x-ray magnetic circular dichroism spectroscopy in a cryogenic ion trap. Three candidates, 6Φ, 8Φ, and 8Γ, for the electronic ground state of Fe 2 + have been identified. These states carry sizable orbital angular momenta that disagree with theoretical predictions from multireference configuration interaction and density functional theory. Our results show that the ground states of neutral and cationic diatomic molecules of 3d transition elements cannot generally be assumed to be connected by a one-electron process.

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Electronic ground states of Fe 2 + and Co 2 + as determined by x-ray absorption and x-ray magnetic circular dichroism spectroscopy

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