Theoretical, Materials and Condensed Matter Physics

Biography

Biography: U P Verma

Abstract

Rare earth filled ternary skutterudite compounds have potential applications to produce clean energy, long-term stability and low cost as compared to other thermoelectric materials. For good efficiency, materials should possess high electrical conductivity, low thermal conductivity, and high Seebeck coefficient. In this communication, the electronic, mechanical and thermoelectric properties of Gd-filled skutterudites GdFe4 P12, GdRu4 P12 and GdOs4 P12 have been reported. The study is based on full potential linearized augmented plane wave method in the framework of density functional theory. The exchangecorrelation potential are treated using the generalized gradient approximation. The electronic behavior of this material is semimetallic. Investigation of mechanical properties shows that reported materials are brittle and anisotropic. GdOs4 P12 is stiffest among GdT4 P12 (T=Fe, Ru, Os). The Boltzmann transport theory with constant relaxation time has been used, as implemented in BoltzTraP code, to predict the thermoelectric properties of all the materials. The magnitude of Seebeck coefficient in spin down channel is more than that in spin up the channel. The maximum values of the figure of merit obtained in spin up channel are 0.44, 0.89 and 0.86 whereas in spin down channel the figure of merit are found to be 0.98, 0.90 and 0.96, respectively for GdFe4P12, GdRu4 P12, and GdOs4 P12. On the basis of the values of ZT, GdRu4 P12 is efficient material in spin up configuration and GdFe4 P12 in spin down configuration. Study of the electronic charge density shows that in the rare earth filled ternary skutterudite compounds have P-P covalent and Gd-B and Fe-B ionic bonding.