| General Review of Static High Magnetic Fields | |
| Static High Magnetic Fields and Materials Science | p. 3 |
| Static High Magnetic Field | p. 5 |
| Materials Science in High Fields | p. 7 |
| References | p. 10 |
| High-T(c) Oxide High Field Superconductors | |
| Vortex Phase Diagram of High-Tc Superconductor YBa(2)Cu(3)O(y) in High Magnetic Fields | p. 13 |
| Melting Transition of the Vortex System | p. 14 |
| First-Order Vortex-Lattice Melting Transition | p. 14 |
| Second-Order Vortex-Glass Melting Transition | p. 16 |
| Second-Peak Effect in Magnetization Hysteresis | p. 16 |
| Vortex Phase Diagram | p. 18 |
| Effect of the Oxygen Deficiency | p. 20 |
| Conclusion | p. 23 |
| References | p. 24 |
| Magnetic Ordering and Superconductivity in La-based High-T(c) Superconductors | p. 27 |
| Sound Velocity and Effects of the Magnetic Field on the Crystal Lattice | p. 27 |
| La-NMR and Antiferromagnetic Spin Ordering | p. 28 |
| Cu/La-NMR in $$$$ | p. 30 |
| La-NMR and Spin Ordering in $$$$ and $$$$ | p. 32 |
| Elastic Properties of the Flux-Line Lattice and Superconductivity | p. 33 |
| Conclusion | p. 38 |
| References | p. 39 |
| Flux-Pinning Properties for CVD Processed YBa(2)Cu(3)O(7) Films | p. 41 |
| Critical Current Measurement | p. 42 |
| Characteristics of CVD-YBCO Films | p. 43 |
| Crossover from Extrinsic to Intrinsic Pinning | p. 44 |
| Temperature-Scaling Law and Irreversibility Field | p. 46 |
| Critical Surface of YBCO | p. 49 |
| Conclusion | p. 51 |
| References | p. 52 |
| Practical Application of High Temperature Superconductors | p. 55 |
| Critical Surface and Critical Current Density Characteristics for High-Temperature Superconductors | p. 56 |
| High-Temperature Superconducting Applications to Current Leads | p. 57 |
| Y123 Current Leads and a Critical-Current Measurement Holder | p. 57 |
| Bi2223 Current Leads and a Cryogenfree Superconducting Magnet | p. 60 |
| Developmental Research of a High-Temperature Superconducting Coil | p. 63 |
| p. 64 |
| References | p. 65 |
| Conventional High-Field Superconductors | |
| Highly Strengthened Nb(3)Sn Superconducting Wires | p. 69 |
| Experimental | p. 70 |
| Stress/Strain Characteristics of Wires | p. 71 |
| Bronze-Processed Nb(3)Sn Wire Reinforcing-Stabilized with Cu-Nb Composite | p. 71 |
| Tube-Processed Nb(3)Sn Wire Reinforcing Stabilized with Alumina-Dispersion-Strengthened Copper | p. 79 |
| Conclusion | p. 80 |
| References | p. 82 |
| Development of Nb3Al Superconductors | p. 85 |
| Variation of Fabrication Process for Nb3Al Superconductors | p. 85 |
| Nb/Al Microcomposite Precursor Wires for the RHQT Process | p. 86 |
| Enhancements in Current Capacities | p. 87 |
| p. 88 |
| Internal Ag Stabilization | p. 89 |
| Mechanical CladdingofCu | p. 89 |
| Combination of Cu-Ion Plating and Cu Electroplating | p. 90 |
| Microstructure of RHQT-Processed Nb(3)Al Wire | p. 92 |
| Additional Effects of Ge and Cu on the Precursor Wire | p. 92 |
| Remark | p. 93 |
| References | p. 94 |
| High-Field A15 Superconductors Prepared Via New Routes | p. 97 |
| Nb(3)(Al,Ge) Superconductors Prepared from $$-Phase/Nb Mixed Powder Core | p. 97 |
| Experimental Procedure | p. 97 |
| Experimental Results | p. 98 |
| Features of this Conductor | p. 99 |
| Nb(3)Sn and (Nb,Ta)(3)Sn Superconductors Prepared from Intermediate Compound Powder | p. 100 |
| Experimental Procedure | p. 100 |
| Experimental Results | p. 101 |
| Features of this Conductor | p. 104 |
| (Nb,Ta)(3)Sn Superconductors Prepared from Ta-Sn Core | p. 104 |
| Conclusion | p. 107 |
| References | p. 108 |
| Magnetic and Optical Properties in High Fields | |
| p. 111 |
| Introduction | p. 111 |
| Properties of Rare-Earth Compounds: Valence Fluctuations and Heavy Fermions | p. 111 |
| Competition Between Kondo Effect and Magnetic Ordering | p. 112 |
| Magnetic and Electrical Properties of Low-Carrier Systems | p. 113 |
| Investigation of the FermiSurface | p. 116 |
| Theoretical Background of the dHvA Effect | p. 116 |
| Experimental Details | p. 117 |
| Negative Pressure Effect on CeSb | p. 119 |
| p. 120 |
| Fermi Surface of GdAs | p. 123 |
| Magnetic Interaction and FermiSurface of TbSb | p. 126 |
| FermiSurfaceofRare-EarthAntimonides | p. 131 |
| Conclusion | p. 132 |
| References | p. 132 |
| High-Field Magnetization Process and Crystalline Electric Field Interaction in Rare-Earth Permanent-Magnet Materials | p. 135 |
| Exchange and Crystal Field Model for the $$$$ System | p. 136 |
| High-Field Magnetization, Spin Reorientation and Magnetostriction in $$$$ | p. 137 |
| Magnetic Properties of c-Axis Oriented SmFe12: a-Fe Nanocomposite Thin Films | p. 141 |
| Conclusion | p. 146 |
| References | p. 147 |
| Study of Covalent Spin Interactions in Cd(1-x)Mn(z)Se by Cryobaric Magneto photo luminescence | p. 149 |
| Experiment | p. 151 |
| Experimental Results | p. 153 |
| Discussion | p. 157 |
| Mean-Field Approximation | p. 157 |
| Analysis of the Experimental Data | p. 161 |
| Conclusion | p. 163 |
| References | p. 164 |
| Other High Field Physical Properties | |
| Magnetic Properties of III-VFerromagnetic Semiconductor (Ga,Mn)As | p. 169 |
| Preparation of (Ga,Mn)As by Molecular Beam Epitaxy and its Lattice Properties | p. 169 |
| Magnetic and Magnetotransport Properties | p. 170 |
| Magnetic Properties | p. 170 |
| Magnetotransport Properties | p. 171 |
| Origin of Ferromagnetism | p. 174 |
| Heterostructures | p. 175 |
| Trilayers | p. 175 |
| Resonant-Tunneling Structures | p. 175 |
| Electrical Spin Injection in Ferromagnetic Semiconductor Heterostructures | p. 176 |
| Conclusion | p. 177 |
| References | p. 177 |
| Transport Properties of the Half-Filled Landau Level in GaAs/AlGaAs Heterostructures: Temperature Dependence of Electrical Conductivity and Magnetoresistance of Composite Fermions | p. 181 |
| Experiments | p. 182 |
| Samples and Measurement Procedures | p. 182 |
| Conductivity of the CFs | p. 184 |
| Magneto resistance of the CFs | p. 186 |
| Discussion | p. 188 |
| Conclusion | p. 189 |
| References | p. 190 |
| Novel Electronic States in Low-Dimensional Organic Conductors | p. 191 |
| Magnetic Breakdown in $$-(BEDT-TTF)(2)Cu(NCS)(2) | p. 192 |
| Hc2 Study of Organic Superconductor $$-(BEDT-TTF)(2)I(3) Under Pressure | p. 195 |
| Magnetoresistance Symmetry of Two-Dimensional Organic $$-Conductors | p. 196 |
| Direct Observation of Reconstructed Fermi Surfaces of (TMTSF)(2)ClO4 Utilizing the Third Angular Effect of Magnetoresistance | p. 202 |
| Conclusion | p. 206 |
| References | p. 207 |
| p. 209 |
| Introduction | p. 209 |
| The $$-(BEDT-TTF)(2)MHg(XCN)(4) Family | p. 209 |
| a-(BEDT-TTF)(2)KHg(SCN)(4): A Novel Density-Wave Metal | p. 209 |
| Magnetic Phase Diagram of $$-(BEDT-TTF)(2)KHg(SCN)(4) | p. 212 |
| Subjects of this Review | p. 213 |
| Experiment and Analysis | p. 214 |
| Samples and Measurements | p. 214 |
| De Haas-van Alphen Oscillations of the Magnetic Torque | p. 215 |
| Spin-Splitting Phenomena in dHvA Oscillations | p. 215 |
| $$-(BEDT-TTF)(2)KHg(SeCN)(4): Normal Metal | p. 215 |
| $$-(BEDT-TTF)(2)KHg(SCN)(4): AF Metal | p. 217 |
| Effective Mass and g-Factor in the Magnetic Phases | p. 218 |
| Problems for the Future | p. 221 |
| Conclusion | p. 222 |
| References | p. 222 |
| NMR/NQR Studies on Magnetism of Spin Ladder Sr(14-x)A(x) Cu(24)O(41)(A=Ca and La) | p. 225 |
| Experimental | p. 226 |
| Hole-Doping Effects on Spin Gaps in Sr(14-x)Ca(x)Cu(24)O(41) | p. 226 |
| Staggered Moments in Sr(14-x)La(x)Cu(24)O(41) | p. 228 |
| Magnetism of Sr(2.5)Ca(11.5)Cu(24)O(41) | p. 231 |
| Conclusion | p. 236 |
| References | p. 237 |
| NMR Study of the Tl-Based High-Tc Cuprate Tl(Ba,Sr)(2)(Y,Ca)Cu(2)O(7) in a Wide Hole Concentration Range from the Antiferromagnetic to the Overdoped Region | p. 239 |
| Experimental | p. 240 |
| Antiferromagnetic Phase of TB1212 | p. 241 |
| Cu-NMRSpectra | p. 241 |
| Tl-NMRSpectra | p. 243 |
| Cu-NMR Relaxation Rate $$ | p. 244 |
| Tl-NMR Relaxation Rate $$ | p. 246 |
| Static Properties of the Antiferromagnetic Phase | p. 246 |
| Dynamical Properties of the Antiferromagnetic Phase | p. 250 |
| Lightly Doped and Slightly Overdoped Phase of Tl1212 | p. 253 |
| Spectra and Relaxation Rate of Tl-NMR | p. 253 |
| Spin-Gapin the Tl-Based System | p. 256 |
| Conclusion | p. 258 |
| References | p. 259 |
| Chemistry, Biology and Crystal Growth in High Fields | |
| Magnetic Levitation | p. 263 |
| Levitation by Means ofa Magnetic Field | p. 264 |
| General Principle | p. 264 |
| Necessity of Negative Susceptibility | p. 269 |
| Levitation Condition for Two Coexisting Materials | p. 271 |
| Origin of the Magnetic Susceptibility | p. 272 |
| Electronsin a ClosedShell of Atoms or Ions | p. 272 |
| Electrons in Molecular Orbits | p. 272 |
| Unpaired Electrons in Atoms or Molecules | p. 273 |
| Conduction Electrons in Metals | p. 273 |
| Electrons in Superconductors | p. 274 |
| Magnetic Levitation Experiments | p. 274 |
| High Field Laboratory for Superconducting Materials (IMR) at Tohoku University | p. 274 |
| Other Facilities in the World | p. 280 |
| Conclusion | p. 281 |
| References | p. 281 |
| p. 283 |
| Crystallization of Protein in a Magnetic Field | p. 283 |
| Orientation ofthe Crystals | p. 285 |
| Growth Rate of Protein Crystals in a Homogeneous Magnetic Field | p. 289 |
| p. 295 |
| Conclusion | p. 298 |
| References | p. 299 |
| Magneto electrochemistry with a Conducting Polymer | p. 301 |
| Magneto electro polymerization | p. 302 |
| Magneto electro polymerized Film Electrodes | p. 304 |
| Control of the Learning Effect | p. 306 |
| Accumulative Effect of the Magnetic Field | p. 308 |
| Future Perspective | p. 309 |
| References | p. 310 |
| Highly Oriented Crystal Growth of Bi-Based Oxide High-Tc Superconductors in High Magnetic Fields | p. 313 |
| Ag-doped Bi2212 Bulk Materials | p. 313 |
| Experimental Procedure | p. 313 |
| CrystalGrowthandProperties | p. 314 |
| Bi2212/Ag Tapes | p. 318 |
| Experimental Procedure | p. 318 |
| Microstructure and Properties | p. 318 |
| Conclusion | p. 321 |
| References | p. 322 |
| Index | p. 323 |
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