A combined experimental and Computational study of the Ca5Si3 phase is presented. Its' electronic Structure and lattice stability are investigated by first principles methods: four different crystal lattices have been investigated by means of density functional theory (DFT) Calculations and pseudopotentials within the generalized-gradient approximation using the VASP code. The Ca5Si3 phase is predicted to undergo an high pressure transition: the lattice transition t132(Cr5B3-type) -> t132(W5Si3-type) has been predicted by DFT to occur at 14.9 GPa. The electronic and band Structure of the t132 Cr5B3-type lattice is calculated and discussed. The Ca5Si3 phase ground state structure is predicted to be a metal with a peaked density of states below the Fermi energy and a sharp minimum right above it, Experimentally the low temperature resistivity and heat capacity of the Ca5Si3 phase have been measured between 2 and 300 K and discussed in view Of Our computational predictions and available literature. The Ca5Si3 t132(Cr5B3-type) standard pressure polymorph exhibits a metallic temperature dependence of the electric conductivity in agreement with the DFT predictions.
Electronic, electrical and thermodynamic properties of Ca5Si3 by first principles calculations and low temperature experimental techniques
MANFRINETTI, PIETRO;CANEPA, FABIO MICHELE
2009-01-01
Abstract
A combined experimental and Computational study of the Ca5Si3 phase is presented. Its' electronic Structure and lattice stability are investigated by first principles methods: four different crystal lattices have been investigated by means of density functional theory (DFT) Calculations and pseudopotentials within the generalized-gradient approximation using the VASP code. The Ca5Si3 phase is predicted to undergo an high pressure transition: the lattice transition t132(Cr5B3-type) -> t132(W5Si3-type) has been predicted by DFT to occur at 14.9 GPa. The electronic and band Structure of the t132 Cr5B3-type lattice is calculated and discussed. The Ca5Si3 phase ground state structure is predicted to be a metal with a peaked density of states below the Fermi energy and a sharp minimum right above it, Experimentally the low temperature resistivity and heat capacity of the Ca5Si3 phase have been measured between 2 and 300 K and discussed in view Of Our computational predictions and available literature. The Ca5Si3 t132(Cr5B3-type) standard pressure polymorph exhibits a metallic temperature dependence of the electric conductivity in agreement with the DFT predictions.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.