Critical currents and superconductivity : ferromagnetism coexistence in high-Tc oxides / Samir Khene, Department of Physics, Faculty of Sciences, Badji Mokhtar University of Annaba, Annaba, Algeria.
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TextPublisher: Boca Raton : CRC Press, Taylor & Francis Group, [2016]Description: 149 pages : illustrations ; 24 cmContent type: text Media type: unmediated Carrier type: volumeISBN: 9781498775106; 1498775101Subject(s): Superconductivity | Critical currents | High temperature superconductors -- Materials | Copper oxide superconductors -- Materials | FerromagnetismDDC classification: 537.6/23 LOC classification: QC611.92 | .K44 2016| Item type | Current library | Call number | Copy number | Status | Notes | Date due | Barcode |
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Female Library | QC611.92 .K44 2016 (Browse shelf (Opens below)) | 1 | Available | STACKS | 51952000238461 | |
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Main Library | QC611.92 .K44 2016 (Browse shelf (Opens below)) | 1 | Available | STACKS | 51952000238454 |
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| QC6 .P367 2016 Fashion, faith, and fantasy in the new physics of the universe / | QC 611 B74 1999 The physics of semiconductors : with applications to optoelectronic devices / | QC611.8.C64 .T55 2016 III-V integrated circuit fabrication technology / | QC611.92 .K44 2016 Critical currents and superconductivity : ferromagnetism coexistence in high-Tc oxides / | QC661 .S66 2006 Electromagnetic waves / | QC 665 .E4 B53 2007 Electromagnetic fields / | QC 665 .E4 G87 2005 Electromagnetic field theory fundamentals / |
"A Science Publishers book."
"The field of superconductivity is constantly evolving. Very important discoveries were made since the beginning of the last century; some of them have even rewarded with Nobel Prizes. In 1911, K.H. Onnes discovered that the electrical resistivity of many metals vanishes below certain very low critical temperatures (Nobel Prize). In 1933, W. Meissner and R. Ochsenfelds showed that cooled to temperatures below its critical temperature, a superconductor expels the magnetic field. In 1935, F. and H. London followed in 1950 by V.L. Ginzburg and L.D. Landau developed phenomenological theories which provided a better understanding of superconductivity (Nobel Prize). Based on these models, A. Abrikosov presented in a theory of the mixed state of type-II superconductors, which stipulates that the magnetic flux penetrates in these materials in the form of vortices (Nobel Prize). The same year, J. Bardeen, L.N. Cooper and J.R. Schrieffers elucidated the physical causes of the superconductivity phenomenon (Nobel Prize). In 1962, B.D. Josephson explained the tunneling junction behavior between the superconductors (Nobel Prize). Around the same time, the discovery of type-II superconductors which support very high magnetic fields (20 teslas) led to their intensive use for the generation of strong fields. In 1986, J.G. Bednorz and K.A. Muller discovered superconductivity in a copper and lanthanum oxide doped with barium with a critical temperature of the order of 30 K (Nobel Prize). This was the beginning of the high-TC superconductors' era. The highest critical temperature reached to date is 133 K in a compound of the type HgBaCan-1CunO2n+2+d with n = 3, at ambient pressure"-- Provided by publisher.
Includes bibliographical references and index.
Superconducting state -- Basic models -- Characteristics of high-Tc superconductors -- Phenomenoligical theories of the anisotropic superconductors -- Dynamic of vortices -- Interactions vortex-vortex, vortex-defect and vortex-spin.
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