4.7 Article

Route to Chemical Accuracy for Computational Uranium Thermochemistry

Journal

JOURNAL OF CHEMICAL THEORY AND COMPUTATION
Volume 18, Issue 11, Pages 6732-6741

Publisher

AMER CHEMICAL SOC
DOI: 10.1021/acs.jctc.2c008126732

Keywords

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Funding

  1. Department of Energy Early Career Research Program
  2. National Science Foundation (NSF)
  3. [DE- SC0020317]
  4. [OAC-1920103]

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Benchmark spinor-based relativistic coupled-cluster calculations were performed to determine the ionization energies of the uranium atom, the uranium monoxide molecule (UO), and the uranium dioxide molecule (UO2), as well as the bond dissociation energies of UO and UO2. The accuracy of the calculations in accounting for relativistic, electron -correlation, and basis-set effects was analyzed. The results demonstrate the unique applicability of the spinor representation of quantum-chemical methods to uranium-containing atomic and molecular species with uranium oxidation states ranging from U(0) to U(V).
Benchmark spinor-based relativistic coupled-cluster calculations for the ionization energies of the uranium atom, the uranium monoxide molecule (UO), and the uranium dioxide molecule (UO2) and for the bond dissociation energies of UO and UO2 are reported. The accuracy of these calculations in the treatments of relativistic, electron -correlation, and basis-set effects is analyzed. The intrinsic convergence of the computed results and the favorable comparison with the experimental values demonstrate the unique applicability of the spinor representation of quantum-chemical methods to open-shell uranium-containing atomic and molecular species with uranium oxidation states ranging from U(0) to U(V).

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