6533b82afe1ef96bd128c3ec
RESEARCH PRODUCT
The first-principles treatment of the electron-correlation and spin-orbital effects in uranium mononitride nuclear fuels.
Eugene HeifetsEugene A. KotominDenis Gryaznovsubject
Tetragonal crystal systemLattice constantCondensed matter physicsMagnetic momentElectronic correlationChemistryQuantum mechanicsAtomDensity of statesGeneral Physics and AstronomyPhysical and Theoretical ChemistrySpin (physics)Ground statedescription
The DFT+U calculations were employed in a detailed study of the strong electron correlation effects in a promising nuclear fuel-uranium mononitride (UN). A simple method for solving the multiple minima problem in DFT+U simulations and insure obtaining the correct ground state is suggested and applied. The crucial role of spin-orbit interactions in reproduction of the U atom total magnetic moment is demonstrated. Basic material properties (the lattice constants, the spin- and total magnetic moments on U atoms, the magnetic ordering, and the density of states) were calculated varying the Hubbard U-parameter. By varying the tetragonal unit cell distortion, the meta-stable states have been carefully identified and analyzed. The difference in the magnetic and structural properties obtained for the meta-stable and ground states is discussed. The optimal effective Hubbard parameter U(eff) = 1.85 eV reproduces correctly the UN anti-ferromagnetic ordering, and only slightly overestimates the experimental total magnetic moment of the U atom and the unit cell volume.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2012-02-25 | Physical chemistry chemical physics : PCCP |