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This page displays all 「FI」 in main group H01F1/00. |
HB:Handbook | ||||
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CC:Concordance | |||||
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Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties | HB | CC | 5E040 | |
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.Antiferromagnetic materials, i.e. materials showing Neel transmission temperatures (H01F1/00, 136 take precedence) | HB | CC | 5E040 | |
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.Diamagnetic or paramagnetic materials, i.e. materials having low magnetic susceptibility and no hysteresis (H01F1/00, 136 take precedence) | HB | CC | 5E040 | |
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.magnetic thick film | HB | CC | 5E040 | |
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.showing low-dimensional magnetism, i.e. rearrangement of spins by restricting dimensions, e.g. showing giant magnetoresistivity (H01F1/153, H01F1/42 and H01F10/00 take precedence) | HB | CC | 5E040 | |
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..zero dimensional, e.g. nanoparticles, soft nanoparticles for medical/biological use | HB | CC | 5E040 | |
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...Coated nanoparticles, e.g. nanoparticles coated with organic surfactants | HB | CC | 5E040 | |
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...in a non-magnetic matrix, e.g. granular solids | HB | CC | 5E040 | |
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..one dimensional, i.e. linear or dendritic nanostructure | HB | CC | 5E040 | |
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...in a non-magnetic matrix, e.g. Fe-nanowires in a nanoporous membrane | HB | CC | 5E040 | |
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..bidimensional, e.g. nanoscale period nanomagnet arrays (H01F10/00 takes precedence) | HB | CC | 5E040 | |
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.of inorganic materials(H01F1/44 takes precedence) [6] | HB | CC | 5E040 | |
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..adapted for magnetic entropy change by magnetocaloric effect, e.g. used as magnetic refrigerating materials | HB | CC | 5E040 | |
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...Metals or alloys | HB | CC | 5E040 | |
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...Compounds | HB | CC | 5E040 | |
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..characterised by their coercivity [6] | HB | CC | 5E040 | |
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...characterised by unspecified or heterogeneous hardness or specially adapted for magnetic hardness transitions | HB | CC | 5E040 | |
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....adapted for large Barkhausen jumps or domain wall rotations, e.g. WIEGAND or MATTEUCCI effect (H01F1/14, 130 and H01F1/153, 191 take precedence) | HB | CC | 5E040 | |
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....Metals or alloys, e.g. LAVES phase alloys of the MgCu2-type (H01F1/03, 104 take precedence) | HB | CC | 5E040 | |
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.....with magnetic shape memory [MSM], i.e. with lattice transformations driven by a magnetic field, e.g. Heusler alloys | HB | CC | 5E040 | |
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....Compounds (H01F1/03, 104 take precedence) | HB | CC | 5E040 | |
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.....Oxidic compounds | HB | CC | 5E040 | |
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......Ferrites | HB | CC | 5E040 | |
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......Manganites | HB | CC | 5E040 | |
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...of hard-magnetic materials [6] | HB | CC | 5E040 | |
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....metals or alloys [6] | HB | CC | 5E040 | |
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.....Alloys characterised by their composition [5, 6] | HB | CC | 5E040 | |
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......containing rare earth elements [5, 6] | HB | CC | 5E040 | |
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.......in a bonding agent | HB | CC | 5E040 | |
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.......sintered | HB | CC | 5E040 | |
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.......and magnetic transition metals, e.g. SmCo5 [6] | HB | CC | 5E040 | |
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........in the form of particles, e.g. quenched powders or ribbon flakes | HB | CC | 5E040 | |
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.........having protection layers | HB | CC | 5E040 | |
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........Obtained by reduction or obtained by the pulverization of hydrogen storage or embrittlement | HB | CC | 5E040 | |
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........pressed, sintered or bonded together | HB | CC | 5E040 | |
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.........pressed | HB | CC | 5E040 | |
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.........sintered | HB | CC | 5E040 | |
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.........bonded together | HB | CC | 5E040 | |
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........and IIIa elements, e.g. Nd2Fe14B [6] | HB | CC | 5E040 | |
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.........in the form of particles, e.g. quenched powders or ribbon flakes | HB | CC | 5E040 | |
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..........having protection layers | HB | CC | 5E040 | |
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..........obtained by reduction or obtained by the pulverization of hydrogen storage or embrittlement | HB | CC | 5E040 | |
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..........obtained by liquid dynamic compaction | HB | CC | 5E040 | |
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..........pressed, sintered or bonded together | HB | CC | 5E040 | |
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...........pressed, e.g. hot working | HB | CC | 5E040 | |
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...........sintered | HB | CC | 5E040 | |
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...........bonded together | HB | CC | 5E040 | |
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.........with exchange spin coupling between hard and soft nanophases, e.g. nanocomposite spring magnets | HB | CC | 5E040 | |
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........and IVa elements, e.g. Gd2Fe14C [6] | HB | CC | 5E040 | |
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........and Va elements, e.g. Sm2Fe17N2 [6] | HB | CC | 5E040 | |
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.........Tetragonal ThMn12 structure | HB | CC | 5E040 | |
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.........orthorhombus or rhombohedron Th2Zn17 structure or hexagonal crystal Th2Ni17 structure | HB | CC | 5E040 | |
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.....in the form of particles, e.g. powder (H01F 1/047 takes precedence) [5, 6] | HB | CC | 5E040 | |
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......having protection layers | HB | CC | 5E040 | |
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......with non-magnetic core | HB | CC | 5E040 | |
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......obtained by reduction | HB | CC | 5E040 | |
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......obtained by liquid dynamic compaction | HB | CC | 5E040 | |
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......with L10 crystal structure, e.g. [Co, Fe][Pt, Pd]particles[nanoparticles] | HB | CC | 5E040 | |
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......pressed, sintered, or bound together [6] | HB | CC | 5E040 | |
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.......in a bonding agent | HB | CC | 5E040 | |
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.......sintered | HB | CC | 5E040 | |
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....mixtures of metallic and non-metallic particles; metallic particles having oxide skin | HB | CC | 5E040 | |
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....non-metallic substances, e.g. ferrites [6] | HB | CC | 5E040 | |
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.....in the form of particles [6] | HB | CC | 5E040 | |
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......with non-magnetic core | HB | CC | 5E040 | |
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......with a film (H01F1/113 takes precedence) | HB | CC | 5E040 | |
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......in a bonding agent [6] | HB | CC | 5E040 | |
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.......Flexible bodies [6] | HB | CC | 5E040 | |
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...of soft-magnetic materials [6] | HB | CC | 5E041 | |
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....metals or alloys [6] | HB | CC | 5E041 | |
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.....in the form of a wire (H01F1/147 takes precedence) | HB | CC | 5E041 | |
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.....Alloys characterised by their composition [5,6] | HB | CC | 5E041 | |
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......Fe-Ni alloys | HB | CC | 5E041 | |
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.......in the form of a sheet | HB | CC | 5E041 | |
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........with insulating coating | HB | CC | 5E041 | |
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.......in the form of particles | HB | CC | 5E041 | |
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........pressed, sintered or bonded together | HB | CC | 5E041 | |
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.........insulated particles | HB | CC | 5E041 | |
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..........by macromolecular organic substances | HB | CC | 5E041 | |
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......Fe-Si alloys | HB | CC | 5E041 | |
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.......in the form of a sheet | HB | CC | 5E041 | |
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........with insulating coating | HB | CC | 5E041 | |
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.......Fe-Si-AI alloys, e.g. Sendust | HB | CC | 5E041 | |
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......Amorphous metallic alloys, e.g. glassy metals [5,6] | HB | CC | 5E041 | |
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.......based on Fe/Ni (H01F1/153, 125 take precedence) | HB | CC | 5E041 | |
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.......based on Co (H01F1/153, 125 take precedence) | HB | CC | 5E041 | |
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.......including rare earths | HB | CC | 5E041 | |
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.......including nanocrystal, e.g. obtained by annealing | HB | CC | 5E041 | |
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.......manufacturing processes | HB | CC | 5E041 | |
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........by powder metallurgy, e.g. spark erosion | HB | CC | 5E041 | |
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.......making agglomerates, e.g. by pressing | HB | CC | 5E041 | |
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........with a binder | HB | CC | 5E041 | |
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.........with a polymer | HB | CC | 5E041 | |
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.......applied by coatings (H01F1/153,166 take precedence) | HB | CC | 5E041 | |
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.......Elongated structure, e.g. wires | HB | CC | 5E041 | |
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.....in the form of sheets (H01F 1/147 takes precedence) [5,6] | HB | CC | 5E041 | |
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......with insulating coating [6] | HB | CC | 5E041 | |
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.....in the form of particles, e.g. powder (H01F 1/147 takes precedence) [5,6] | HB | CC | 5E041 | |
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......pressed, sintered, or bound together [6] | HB | CC | 5E041 | |
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.......the particles being insulated [6] | HB | CC | 5E041 | |
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........by macromolecular organic substances [6] | HB | CC | 5E041 | |
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......dispersed or suspended in a bonding agent [6] | HB | CC | 5E041 | |
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....mixtures of metallic and non-metallic particles; metallic particles having oxide skin [6] | HB | CC | 5E041 | |
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....non-metallic substances, e.g. ferrites [6] | HB | CC | 5E041 | |
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.....Oxides (H01F1/36 and H01F1/38 take precedence) | HB | CC | 5E041 | |
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......Ferrites, e.g. magnetite Fe304 | HB | CC | 5E041 | |
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.......Garnet-type (H01F10/24 takes precedence) | HB | CC | 5E041 | |
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.......Hexagonal ferrites with low rigidity or anisotropy, i.e. with increased permeability in the microwave range, e.g. having a hexagonal crystallographic structure | HB | CC | 5E041 | |
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.....in the form of particles [6] | HB | CC | 5E041 | |
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......in a bonding agent [6] | HB | CC | 5E041 | |
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.......Flexible bodies [6] | HB | CC | 5E041 | |
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.....Amorphous, e.g. amorphous oxides [6] | HB | CC | 5E041 | |
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..Materials for magnetic semiconductors, e.g. CdCr2S4 [6] | HB | CC | 5E040 | |
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...Materials for dilute magnetic semiconductors | HB | CC | 5E040 | |
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....II-V type, e.g. Zn1-xCrxSe | HB | CC | 5E040 | |
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....III-V type, e.g. In1-MnxAs | HB | CC | 5E040 | |
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....IV type, e.g. Ge1-xMnx | HB | CC | 5E040 | |
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....Diluted non-magnetic ions in a magnetic cation-sublattice, e.g. La1-x(Ba,Sr)xMnO3 | HB | CC | 5E040 | |
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...Semimetal, i.e. with one-direction electric spin at Fermi level, e.g. CrO2, Heusler alloy (H01F10/193 takes precedence) | HB | CC | 5E040 | |
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.of organic or organo-metallic materials(H01F1/44 takes precedence) [6] | HB | CC | 5E040 | |
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.Magnetic liquids, e.g. ferroliquids [6] | HB | CC | 5E041 | |
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..The magnetic component being a metal or alloy, e.g. Fe (H01F1/44, 170 take precedence) | HB | CC | 5E041 | |
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..The magnetic component being a compound, e.g. Fe3O4(H01F1/44, 170 take precedence)} | HB | CC | 5E041 | |
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..characterised by magnetoviscosity, e.g. magnetorheological, magnetothixotropic, magnetodilatant liquids | HB | CC | 5E041 | |