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Mechanical and Thermal Properties for Uranium and U–6Nb Alloy from First-Principles Theory

Per Söderlind, Lin Yang, A. Landa, Amanda S. Wu

2021Applied Sciences12 citationsDOIOpen Access PDF

Abstract

Elasticity, lattice dynamics, and thermal expansion for uranium and U–6Nb alloy (elastic moduli) are calculated from density functional theory that is extended to include orbital polarization (DFT+OP). Introducing 12.5 at.% of niobium, substitutionally, in uranium softens all the cii elastic moduli, resulting in a significantly softer shear modulus (G). Combined with a nearly invariant bulk modulus (B), the quotient B/G increases dramatically for U–6Nb, suggesting a more ductile material. Lattice dynamics from a harmonic model coupled with a DFT+OP electronic structure is applied for α uranium, and the obtained phonon density of states compares well with inelastic neutron-scattering measurements. The Debye temperature associated with the lattice dynamics falls within the range of experimentally observed Debye temperatures and it also validates our quasi-harmonic (QH) phonon model. The QH Debye–Grüneisen phonon method is combined with a DFT+OP electronic structure and used to explore the anisotropic thermal expansion in α uranium. The anomalous negative thermal expansion (contraction) of the b lattice parameter of the α-phase orthorhombic cell is relatively well reproduced from a free-energy model consisting of QH-phonon and DFT+OP electronic structure contributions.

Topics & Concepts

Debye modelCondensed matter physicsPhononThermal expansionMaterials scienceDensity functional theoryBulk modulusOrthorhombic crystal systemShear modulusElastic modulusDensity of statesNegative thermal expansionThermodynamicsCrystal structureCrystallographyChemistryPhysicsComputational chemistryComposite materialNuclear Materials and PropertiesRare-earth and actinide compoundsThermodynamic and Structural Properties of Metals and Alloys