High-precision electron affinity of oxygen

Kristiansson, M. K.; Chartkunchand, K. C.; Eklund, Gustav; Hole, Odd Magnar; Anderson, E. K.; Ruette, N. de; Kamińska, Magdalena; Najeeb, P. K.; Navarro-Navarrete, José E.; Sigurdsson, Stefan; Grumer, Jon; Simonsson, Ansgar; Björkhage, Mikael; Rosén, Stefan; Reinhed, Peter; Blom, Mikael; Källberg, A.; Alexander, John D.; Cederquist, H.; Zettergren, Henning; Schmidt, H. T.; Hanstorp, Dag

doi:10.1038/s41467-022-33438-y

Cited by 18 publications

(4 citation statements)

References 53 publications

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“…Thus, the description of anionic states is a hard test for the ANO-R basis set. The electron affinity (EA) of oxygen is well-known experimentally with a very high precision (1.461 112 972(87) eV). Theoretical studies, with close to exact methods, predict an EA of oxygen in the range of 1.26 to 1.29 eV .…”

Section: Basis Sets Ab Initio Model Potentials and Orbital Rotationmentioning

confidence: 99%

The OpenMolcas Web: A Community-Driven Approach to Advancing Computational Chemistry

Manni

Galván

Alavi

et al. 2023

J. Chem. Theory Comput.

106

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The developments of the open-source chemistry software environment since spring 2020 are described, with a focus on novel functionalities accessible in the stable branch of the package or via interfaces with other packages. These developments span a wide range of topics in computational chemistry and are presented in thematic sections: electronic structure theory, electronic spectroscopy simulations, analytic gradients and molecular structure optimizations, ab initio molecular dynamics, and other new features. This report offers an overview of the chemical phenomena and processes can address, while showing that is an attractive platform for state-of-the-art atomistic computer simulations.

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Section: Basis Sets Ab Initio Model Potentials and Orbital Rotationmentioning

confidence: 99%

The OpenMolcas Web: A Community-Driven Approach to Advancing Computational Chemistry

Manni

Galván

Alavi

et al. 2023

J. Chem. Theory Comput.

106

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“…Since the added electron in O 2 – is an antibonding electron, the electron attachment energy is a larger negative value for an oxygen atom than for the oxygen molecule, so the right side of this equation is negative. Therefore, the bond energy of O 2 – is less than the bond energy of O 2 , based on documented values for oxygen: ,,,, B E false( O 2 − false) − B E false( O 2 false) = E A false( O false) − E A false( O 2 false) = − 141 k J m o l − true( prefix− 86 k J m o l true) = − 55 k J m o l The addition of the antibonding electron weakens the bond by 55 kJ/mol. This is consistent with the qualitative prediction based on the bond order being reduced from 2 to 3/2.…”

Section: A Quantitative Approachmentioning

confidence: 99%

Relating Bond Orders and Bond Energies to Ionization Energies and Electron Affinities: A Quantitative Approach

Hutchinson,

Tran Lu,

Kincaid

2024

J. Chem. Educ.

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In General Chemistry, students are often asked to predict changes in bond energy based on changes in bond order when electrons are either added to or removed from a molecule. This gives a qualitative understanding of the correlation between bond order and bond energy, but it is not descriptive of the actual changes in the bond energies involved. In this paper, we present a quantitative approach to this prediction based on ionization energy, electron affinity, and conservation of energy (or Hess' law). These are all concepts that are familiar to General Chemistry students. With this quantitative approach, we can more fully illustrate how bonding and antibonding electrons contribute to bond strength and better relate these to ionization energies and electron affinities. Multiple examples are given to illustrate a range of possibilities and to compare variations of bond energies.

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“…When making MO À species from MO 0 the additional electron is practically always placed into the 4s M orbital and not on the more electronegative oxygen terminal. The electron affinity (EA) values for the first-row transition metal monoxides range experimentally between 1.22 (CrO) and 1.54 (CoO) eV, [77][78][79][80][81][82][83][84] which is fortuitously close to the 1.46 eV 85 EA of the oxygen atom. Finally, we refer to the destiny of the 4s M electrons upon ligation, which is not discussed in the chemistry textbooks.…”

Section: Perspective Pccpmentioning

confidence: 99%

Transition metal oxide complexes as molecular catalysts for selective methane to methanol transformation: any prospects or time to retire?

Claveau

Sader

Jackson

et al. 2023

Phys. Chem. Chem. Phys.

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High-precision electron affinity of oxygen

Cited by 18 publications

References 53 publications

The OpenMolcas Web: A Community-Driven Approach to Advancing Computational Chemistry

The OpenMolcas Web: A Community-Driven Approach to Advancing Computational Chemistry

Relating Bond Orders and Bond Energies to Ionization Energies and Electron Affinities: A Quantitative Approach

Transition metal oxide complexes as molecular catalysts for selective methane to methanol transformation: any prospects or time to retire?

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