Behavior of the irreversibility line in the new superconductor LU3-XGD XBA5CU8O 18 FOR X = 1.5 AND X = 2
Palabras clave:
Magnetization, Irreversibility Line, High Critical Temperature Superconductors, Method solid state reactionResumen
The irreversibility properties of High-Tc superconductors are of major importance for technological applications. For example, a high irreversibility magnetic field is a more desirable quality for a superconductor (Viera, et al., 2001). The irreversibility line in the H-T plane is constituted by experimental points, which divides the irreversible and reversible behavior of the magnetization. The irreversibility lines for series of Lu1Gd2Ba5Cu8O18 and Lu 1.5 Gd Ba Cu O polycrystalline samples with different doping were investi- 1.5 5 8 18 gated. The samples were synthesized using the usual solid estate reaction method. Curves of magnetization ZFC (Zero Field Cooled) FC (Field Cooled) for the system Lu Gd Ba Cu O and Lu Gd Ba Cu O , were measured in 1 2 5 8 18 1.5 1.5 5 8 18 magnetic fields of the 100 to 2,000 Oe, and allowed to obtain the values for the irreversibility and critical temperatures. The data of irreversibility temperature allowed demarcating the irreversibility line, T H). Two main lines are used for irr(the interpretation of the irreversibility line: one of those which suppose that the vortexes are activated thermally and the other proposes that associated to Tirr
(Irreversibility Temperature) a phase transition occurs. The irreversibility line is described by a power law. The obtained results allow concluding that in the system Lu Gd Ba Cu O and Lu Gd Ba Cu O a characteristic bend of the 1 2 5 8 18 1.5 1.5 5 8 18 Almeida-Thouless (AT) tendency is dominant for low fields and a Gabay- Toulouse (GT) behavior for high magnetic fields.
Biografía del autor/a
Daniel Augusto Castellanos Coronado, University of Pavia
Laboratory of Integrated Microsystems-University of Pavia
Franco Maloberti, University of Pavia
Laboratory of Integrated Microsystems-University of Pavia
Edoardo Bonizzoni, University of Pavia
Laboratory of Integrated Microsystems-University of Pavia
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