• HOME
  • Search & Results
  • Full Text
  • Thesis Details
 
Page: 201
 
 Full Screen

  • TITLE
  • CERTIFICATE-1
  • CERTIFICATE-2
  • DECLARATION
  • ACKNOWLEDGEMENT
  • CONTENTS
  • PREFACE
  • LIST OF PUBLICATIONS
  • LIST OF PATENTS
  • I. Introduction
  • I.1 Superconductivity
  • I.2 Properties of Superconductors
  • I.3 High Temperature Superconductors
  • I.3.1 Y-Ba-Cu-O. System
  • Table 1.1 List of major high temperature superconductors
  • Fig. I.I Geometrical diagram representing the crystal structure of (A) Orthorhombic (B) Tetragonal phases of YBa2Cu3O7
  • Fig.I.2 X-ray diffraction patterns of YBa2Cu3O7-8 (A) OrthorhombicB) Tetragonal phases
  • Table 1.2 X-ray diffraction data of YBa2Cu3Ox,
  • Fig. 1.3 Variation of critical temperature (TC) with oxygen stoichiometry x (=7-6) in YBa2Cu3O7-8
  • I.3.2 Bi-Sr-Ca-Cu-O System
  • Fig 1.4 Compatibility regions in the pseudoternary Y2O3-BaO-CuO systemas determined at 950°C
  • I.3.3 Tl-Ba-Ca-Cu-O System
  • I.3.4 Hg-Ba-Cu-O System
  • I.4 Effect of Oxidic Additions and Substitutions in YBa2Cu3O7-8
  • I.5 YBa2Cu3O7-8 Thick films
  • I.6 Substrates for YBa2Cu3O7-8 Films
  • Table 1.4 Physical properties of substrates used for YBCO films
  • References
  • II. Experimental Methods
  • II.1 Processing of YBa2Cu3O7-8 Superconductors
  • II.2 Processing of REBa2HfO5.5 [RE= Y, Gd, Sm] Ceramic Substrates
  • II.3 Experimental set up for the fabication of YBa2Cu3O7-8 thick films
  • II.3.1 Screen Printing
  • II.3.2 Dip-coating
  • Fig 11.1 Schematic diagram of screen printing apparatus
  • II.4 X-ray Powder Diffraction Technique
  • Fig.II.2. Schematic diagram for the Debye Scherrer x-ray powder method
  • II.5 Scanning Electron Microscope
  • II.6 Electrical Measurements
  • II.6.1 Resistivity and Critical Temperature Measurements-Vander-Pauw Method.
  • Fig 11.5 Sample holder set up to measure the electrical resistivityof the samples.
  • II.6.2 Critical Current Density Measurements
  • II.7 Measurement of Dielectric Properties
  • References
  • III. Effect of Hafnium Oxide Addition in YBa2Cu3O7-8 Superconductors
  • III.1.Introduction
  • III.2 Sample Preparation
  • III.3 Characterisation of Hf02 added YBa2Cu307-8 samples
  • III.3.1 X-ray Diffraction Studies
  • III.3.2 Temperature-Resistivity Measurements
  • III.3.3 Surface Morphology
  • Fig. III.3 Scanning Electron Micrograph of (A) pure YBCO (B) 5wt. % HfO, added YBCO (Magnification 2000)
  • III.4 Enhanced Oxygen absorption in Hf02 added YBa2Cu3O7-8 samples
  • III.4.1 Sample Preparation and Quenching Procedure
  • III.4.2 Structural Analysis
  • III.4.3 Temperature-Resistivity Measurements
  • III.5 Discussion
  • Referens
  • IV. Synthesis and characterisation of REBa2HfO5.5 [RE=Y, Gd, Sm]-A new class of Ceramic Compounds
  • IV. 1 Introduction
  • IV.2 Preparation of REBa2HfO5.5
  • IV.3 Crystal structure of REBa2HfO5.5
  • Fig IV.2. Crystal structure diagram of KEBa2I-HfO5
  • IV.4 Sintered Density and Resistivity Measurements
  • IV.5 Measurement of Dielectric Properties
  • IV.6 Surface Morphology of REBa2HfO5 5
  • Fig.IV.7 Optical micrographs of (A) YBa2HfO, (B) GdBa2HfO,, (C) SmBa2HfO,, (Magnification 800)
  • IV.7 Chemical Compatibility of REBa2HfO5 5 with YBa2Cu3O7-8
  • IV.8 Discussions
  • Referens
  • V. Electrical Transport and Percolation study in YBa2Cu3O7-8 -REBa2HfO5.5Superconductor-Insulator Composite
  • V.1 Introduction
  • V.2 Percolation Model
  • V.3 YBa2Cu3O7-8 YBa2HfO5 5 Percolation System
  • V.3.1 Preparation of YBa2Cu3O7-8-YBa2HfO5 5 Composites
  • V.3.2 X-ray Diffraction Studies on YBa2Cu3O7-8 YBa2HfO5 5 Composites
  • V.3.3 Temperature-Resistivity Measurements on YBa2Cu3O7-8 YBa2HfO5 5 Composites
  • V.4 YBa2Cu3O7-8-GdBa2HfO5 5 Percolation System
  • V.4.1 Preparation of YBa2Cu3O7-8-GdBa, HfO5.5 Composites
  • V.4.2 X-ray Diffraction Studies on YBa2Cu3O7-8 GdBa2HfO5 5 Composites
  • V.4.3 Temperature-Resistivity Measurements on YBa2Cu3O7-8-GdBa2HfO5.5 Composites
  • V.5 YBa2Cu3O7-8-SmBa2HfO5.5 Percolation System
  • V.6 Percolation Study in YBa2Cu3O7-8 YBa2HfO5 5 Rapidly Quenched Samples
  • V.7 Discussions
  • References
  • VI. Preparation of YBa2Cu3O7_SThick Films on REBa2HfO5 5 [RE=Y, Gd, Sm] Substrates by Screen Printing
  • VI.1 Introduction
  • VI.2 Screen Printing of YBa2Cu3O7-8Thick Films on REBa2HfO5 5 Substrates
  • VI.3 Structural Characterisation of Screen Printed YBa2Cu3O7-8 Thick Films
  • VI.4 Temperature-Resistivity Measurements of Screen Printed YBa2Cu30, -8Thick Films
  • VI.5 Surface Morphology of Screen Printed YBa2Cu30, -8Thick Films
  • VI 6 Discussions
  • References
  • VII. Fabrication of YBa2Cu30sThick Films on REBa2HfO5 s [RE= Y, Gd, Sm] Substrates by Dip coating
  • VII.1 Introduction
  • VII.2 Preparation of Dip coated YBa2Cu3O7-8Thick Films on REBa2HfO55 [RE= Y, Gd, Sm] on Substrates
  • VII.3 X-ray Diffraction Analysis
  • VII.4 Temperature-Resistivity Measurements
  • VII.5 Microstructure of the Films
  • VII.6 Discussions
  • References
  • VIII. Preparation of YBa2Cu3O7-8-Silver Composite Thick Films on REBa2HfO5 5 [R]E=Y, Gd, Sm] substrates
  • VIII. 1 Introduction
  • VIII. 2 Preparation of YBa2Cu3O7-8-Ag Composite
  • VIII. 3 Preparation of YBa2Cu3O7-8-Ag Composite Thick Films on REBa2Hf05.5 [RE=Y, Gd, Sm] Substrates
  • VIII. 4 X-ray Diffraction Studies on YBa2Cu3O7-8-Ag Composite Thick Films
  • VIII. 5 Temperature-Resistivity Measurements
  • VIII. 6 Micro structural Analysis
  • VIII.7 Discussions
  • References
  • IX. Summary and Conclusions
  • Scope of Future Investigations