Electronic structure and thermoelectric properties on transition-element-doped clathrates

Abstract

Transition element(TM) doping for group IV clathrates is very interesting from the viewpoint of p-type thermoelectric materials. Group IV clathrates are candidates of high performance thermoelectric materials, because they show low thermal conductivity and high carrier mobility. But almost all clathrate semiconductors show n-type conduction due to excess electrons brought by alkali or alkaline-earth metal elements. We have studied the doping effects of noble metal elements on the electronic structure and thermoelectric properties by means of computational approaches. The electronic structure is calculated by the Full-potential Linearized Augmented Plane Wave (FLAPW) method with the Generalized Gradient Approximation (GGA) based on the density functional theory. The calculated electronic structure shows that TM-substituting clathrates Ba/sub 8/M/sub 6/X/sub 40/(M=Cu, Ag, Au; X=Si, Ge) are p-type semiconductors and have large thermoelectric power(/spl alpha/) at room temperature. The calculated energy of the band gap E/sub g/ is 302 meV in Ba/sub 8/Au/sub 6/Ge/sub 40/, which is smaller than that in Ba/sub 8/Ga/sub 16/Ge/sub 30/(E/sub g/=513 meV ). When La atoms are doped at guest sites, the band gap becomes large: E/sub g/=353 meV(La/sub 2/Ba/sub 6/Au/sub 6/Ge/sub 40/). By using a rigid band and a constant relaxation time approximation, we have calculated the thermoelectric properties. For La/sub 2/Ba/sub 6/Au/sub 6/Ge/sub 40/, we obtained /spl alpha/=240 /spl mu/V/K at a hole concentration n/sub h/=10/sup 20//cm/sup 3/ and at 300 K.