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Research PapersNo Access

CRITICAL STATE MODELS FOR GRANULAR MAGNETIC SUPERCONDUCTOR RuSr₂GdCu₂O₈

Physics Department, Al-Quds University, CST, P. O. Box 20002, Jerusalem, West Bank, Palestine, via, Israel

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,

Physics Department, Al-Quds University, CST, P. O. Box 20002, Jerusalem, West Bank, Palestine, via, Israel

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,

M. M. ABU-SAMREH

Physics Department, Al-Quds University, CST, P. O. Box 20002, Jerusalem, West Bank, Palestine, via, Israel

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, and

R. M.-L. KITANEH

Physics Department, Al-Quds University, CST, P. O. Box 20002, Jerusalem, West Bank, Palestine, via, Israel

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https://doi.org/10.1142/S0217979208038193Cited by:0 (Source: Crossref)

Abstract

A systematic investigation of the ac susceptibility of polycrystalline RuSr₂GdCu₂O₈ was carried out with different field amplitudes and various frequencies. The study covered a wide range of frequencies between 0.020 to 12.5 kHz and temperatures from 7 to 50 K. The first derivative of susceptibility curves indicated the presence of a superconducting intragranular transition coupled by weak links distribution of intergranular transitions. The intragranular-, χ_g, and intergranular-, χ_i contribution to susceptibility were estimated and found to be consistent with the prediction of the critical state model. Variation of the peak temperature of the imaginary part with frequency was employed to determine the vortex activation energy. The derived low activation energy values provide clear evidence of the thermally activated flux creep process in the superconducting state. Qualitative analysis of the χ′′ - χ′ parametric relation was carried out.

Keywords:

PACS: 74.60.Ge, 74.72.-h, 75.50.-y

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Vol. 22, No. 13

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Received 10 November 2006

Keywords