Data di Pubblicazione:
2007
Abstract:
The formation, phase relations, crystal chemistry and physical properties were investigated for the solid solution Ba8ZnxGe46−x−yy deriving from binary
clathrate Ba8Ge433 with a solubility limit of 8 Zn atoms per formula unit at 800 ◦C ( is a vacancy). Single-crystal x-ray data throughout the homogeneity region confirm the clathrate type I structure with cubic primitive space group type Pm¯3n.
Temperature-dependent x-ray spectra as well as heat capacity define a lowlying, almost localized, phonon branch, whereas neutron spectroscopy indicates a phonon mode with significant correlations. The transport properties are strongly determined by the Ge/Zn ratio in the framework of the structure.
Increasing Zn content drives the system towards a metal-to-insulator transition; for example, Ba8Zn2.1Ge41.52.4 shows metallic behaviour at low temperatures, whilst at high temperatures semiconducting features become obvious. A
model based on a gap of the electronic density of states slightly above the Fermi energy was able to explain the temperature dependences of the transport properties. The thermal conductivity exhibits a pronounced low-temperature maximum, dominated by the lattice contribution, while at higher temperatures the electronic part gains weight. Zn-rich compositions reveal attractive Seebeck coefficients approaching −180 μV K−1 at 700 K.
clathrate Ba8Ge433 with a solubility limit of 8 Zn atoms per formula unit at 800 ◦C ( is a vacancy). Single-crystal x-ray data throughout the homogeneity region confirm the clathrate type I structure with cubic primitive space group type Pm¯3n.
Temperature-dependent x-ray spectra as well as heat capacity define a lowlying, almost localized, phonon branch, whereas neutron spectroscopy indicates a phonon mode with significant correlations. The transport properties are strongly determined by the Ge/Zn ratio in the framework of the structure.
Increasing Zn content drives the system towards a metal-to-insulator transition; for example, Ba8Zn2.1Ge41.52.4 shows metallic behaviour at low temperatures, whilst at high temperatures semiconducting features become obvious. A
model based on a gap of the electronic density of states slightly above the Fermi energy was able to explain the temperature dependences of the transport properties. The thermal conductivity exhibits a pronounced low-temperature maximum, dominated by the lattice contribution, while at higher temperatures the electronic part gains weight. Zn-rich compositions reveal attractive Seebeck coefficients approaching −180 μV K−1 at 700 K.
Tipologia CRIS:
1.1 Articolo in rivista
Keywords:
clathrate; thermoelectric properties; transport; electronic structure; density of states
Elenco autori:
MELNYCHENKO KOBLYUK, N.; Grytsiv, A.; Fornasari, Lucia; Kaldarar, H.; Michor, H.; Rohrbacher, F.; Koza, M.; Royanian, E.; Bauer, E.; Rogl, P.; Rotter, M.; Schmid, H.; Marabelli, Franco; Devishvili, A.; Doerr, M.; Giester, G.
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