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The study of magnetodielectric behaviors in spin frustrated Cu2Te2O5X2 (X=Cl and Br) compoundsYeh, Chin-Chia 28 June 2012 (has links)
An intriguing magnetodielectric (MD) behavior is observed in geometrically frustrated spin-tetrahedral systems Cu2Te2O5X2 (X = Cl and Br). While the phase transition observed in the Cl-system at TN=18.5 K is consistent with 3D antiferromagnetic ordering, the phase transition at To=11.5 K in the Br-system has several unusual features. Concomitantly, a pronounced ferroelectric ordering is observed coinciding with TN of Cl-system and To of Br-system. At the highest applied magnetic field 90 kOe, the temperature dependent dielectric behavior with almost frequency independent well defined at TN~18.5 K are decrease compared with that at zero field for Cl-system, and at the highest applied magnetic field 90 kOe, the temperature dependent dielectric behavior with almost frequency independent well defined at Tm~30 K are decrease compared with that at zero field for Br-system. The ferroelectricity is ascribed to the polarization of the Te4+ lone-pair electrons, while the MD effect is argued to be due to exchange interaction involving frustrated tetramer clusters and intercluster exchange bridges.
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The study od magnetodielectric behaviors in frustrated Cu2Te2O5Br2 compoundChin, Yi-Pin 22 July 2011 (has links)
An intriguing magnetodielectric behavior is observed in triangular or tetrahedral frustrated and low-dimensional system. Therefore, the spin-tetrahedral and low-dimensional compound copper-tellurides (Cu2Te2O5Br2) is suggested that has magnetodielectric behavior. Tetragonal Cu2Te2O5Br2 contains clusters of four Cu2+ (S = 1/2) in a planar coordination. These tetrahedral form weakly coupled sheets within the crystallographic a-b plane. Therefore, this system is ideal to study the interplay between the spin frustration on a tetrahedron with localized low-energy excitations and collective magnetism induced by inter-tetrahedral couplings. In this material a strongly reduced magnetic transition temperature To = 11.5 K in comparison with a dominant magnetic exchange of 30 K is found. Low-dimensional systems with triangular geometries are considered as prominent candidates for applications using novel magnetoelectric materials. At the highest applied magnetic field 90 kOe, the temperature dependent dielectric behavior with almost frequency independent well defined maxima at Tm ~ 30 K and To ~ 11.5 K are enhanced compared with that at zero field. We suggest that the observed magnetodielectric coupling can arise from exchange striction involving frustrated tetramer clusters and inter-cluster exchange bridges with polarizable lone-pair electrons on Te4+ ions.
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