Oxide electronics

Spin singlet formation in MgTi$_2$O$_4$: evidence of a helical dimerization pattern

ArXiv cond-mat/0308101 (2003)

Authors:

M Schmidt, W Ratcliff II, PG Radaelli, K Refson, NM Harrison, SW Cheong

Abstract:

The transition metal spinel MgTi$_2$O$_4$ undergoes a metal-insulator transition on cooling below $T_{M-I} = 260$ K. A sharp reduction of the magnetic susceptibility below $T_{M-I}$ suggests the onset of a magnetic singlet state. Using high-resolution synchrotron and neutron powder diffraction, we have solved the low-temperature crystal structure of MgTi$_2$O$_4$, which is found to contain dimers with short Ti-Ti distances (the locations of the spin singlets) alternating with long bonds to form helices. Band structure calculations based on hybrid exchange density functional theory show that, at low temperatures, MgTi$_2$O$_4$ is an orbitally ordered band insulator.

High Performances Corrugated Feed Horns for Space Applications at Millimetre Wavelengths

(2003)

Authors:

F Villa, M Sandri, N Mandolesi, R Nesti, M Bersanelli, A Simonetto, C Sozzi, O D'Arcangelo, V Muzzini, A Mennella, P Guzzi, P Radaelli, R Fusi, E Alippi

Erratum: Structural transformation induced by magnetic field and "colossal-like" magnetoresistance response above 313 K in MnAs (Phys. Rev. Lett. (2003) 90 (097203))

Physical Review Letters 90:18 (2003)

Authors:

J Mira, F Rivadulla, J Rivas, A Fondado, T Guidi, R Caciuffo, F Carsughi, PG Radaelli, JB Goodenough

Temperature-induced barium de-trapping from a double-well potential in Ba6Ge25

(2003)

Authors:

M Schmidt, PG Radaelli, MJ Gutmann, SJL Billinge, N Hur, SW Cheong

Temperature-induced barium de-trapping from a double-well potential in Ba6Ge25

ArXiv cond-mat/0303247 (2003)

Authors:

M Schmidt, PG Radaelli, MJ Gutmann, SJL Billinge, N Hur, SW Cheong

Abstract:

The crystal structure of barium-germanium clathrate Ba6Ge25 was studied using neutron powder diffraction in the temperature range 20-300K. The compound was found to be cubic (S.G. P4_1 23) in the entire temperature range. However, the fully-ordered model of the crystal structure (no split sites) is marginal at room temperature, and clearly fails at low temperature. A much better description of the crystal structure below 250K is given in terms of two split Ba sites, with random occupancies, for two out of three types of cages present in the Ba6Ge25 structure. The Ba atoms were found to interact strongly with the Ge host. The separation of the split Ba sites grows with decreasing temperature, with a sudden increase on cooling through the 200-250K temperature range, accompanied by an expansion of the entire crystal structure. We propose a simple model for this transition, based on temperature-induced de- trapping of Ba from a deep double-well potential. This transition is associated with sizeable anomalies in the transport and magnetic properties. The most significant of these effects, that is, the drop in electrical conductivity on cooling, can be easily explained within our model through the enhanced structural disorder, which would affect the relaxation time for all portions of the Fermi surface. We suggest that the other anomalies (increase in the absolute value of the negative Seebeck coefficient, decrease in the magnetic susceptibility) can be explained within the framework of the one-electron semi- classical model, without any need to invoke exotic electron-electron interaction mechanisms.