The present invention provides a process for production of a magnetic thin film which has insulation properties, serves as a permanent magnet, and has improved residual magnetization in comparison with prior arts, the magnetic thin film, and a magnetic material. When a magnetic thin film 3 is formed, an external magnetic field with a predetermined intensity is applied to a coating liquid containing magnetic particles containing epsilon-type iron-oxide-based compounds which have insulation properties and which serve as a permanent magnet, and the coating liquid is let cured in order to form the magnetic thin film 3. Accordingly, the magnetic particles containing the epsilon-type iron-oxide-based compounds can be fixed while being oriented regularly in a magnetization direction. This realizes the process for production of the magnetic thin film 3 which has insulation properties and which serve as a permanent magnet, the magnetic thin film 3, and a magnetic material 1.

A method of making a ferrite thin film is provided in which a portion of the iron ions in the ferrite are substituted by ions of at least one other metal. The substituting ions occupy both tetrahedral and octahedral sites in the unit cell of the ferrite crystal. The method includes placing each of a plurality of targets, one at a time, in close proximity to a substrate in a defined sequence; ablating the target thus placed using laser pulses, thereby causing ions from the target to deposit on the substrate; repeating these steps, thereby generating a film; and annealing the film in the presence of oxygen. The plurality of targets, the sequence of their ablation, and the number of laser pulses that each target is subjected to, are selected so as to allow the substituting ions to occupy both tetrahedral and octahedral sites in the unit cell.

An object of the present invention is to provide a new nanogranular structure material having magneto-optical properties different from those of existing nanogranular structure materials, and a method for producing the same. The nanogranular structure material has a composition represented by L-M-FO wherein L is at least one element selected from the group consisting of Fe, Co, and Ni, and M is at least one element selected from the group consisting of Li, Be, Mg, Al, Si, Ca, Sr, Ba, Bi, and rare earth elements, F is fluorine, and O is oxygen. The nanogranular structure material according to the present invention is composed of a matrix formed of a fluorine compound having a composition represented by M-F and metal oxide nanoparticles dispersed in the matrix and having a composition represented by L-O.

An object of the present invention is to provide a new nanogranular structure material having magneto-optical properties different from those of existing nanogranular structure materials, and a method for producing the same. The nanogranular structure material has a composition represented by L-M-FO wherein L is at least one element selected from the group consisting of Fe, Co, and Ni, and M is at least one element selected from the group consisting of Li, Be, Mg, Al, Si, Ca, Sr, Ba, Bi, and rare earth elements, F is fluorine, and O is oxygen. The nanogranular structure material according to the present invention is composed of a matrix formed of a fluorine compound having a composition represented by M-F and metal oxide nanoparticles dispersed in the matrix and having a composition represented by L-O.

Forming a ferrite thin film laminate includes heating a layered assembly to form a laminate. The layered assembly includes a first coated substrate having a first ferrite layer opposite a first thermoplastic surface and a second coated substrate having a second ferrite layer opposite a second thermoplastic surface to form a laminate. Each coated substrate is formed by forming a ferrite layer on a surface of a thermoplastic substrate. The coated substrates are arranged such that the first ferrite layer contacts the second thermoplastic surface. Heating the layered assembly includes bonding the first coated substrate to the second coated substrate such that the first ferrite layer is sandwiched between a first thermoplastic substrate and a second thermoplastic substrate. The ferrite thin film laminate may include a multiplicity of coated substrates.

Forming a ferrite thin film laminate includes heating a layered assembly to form a laminate. The layered assembly includes a first coated substrate having a first ferrite layer opposite a first thermoplastic surface and a second coated substrate having a second ferrite layer opposite a second thermoplastic surface to form a laminate. Each coated substrate is formed by forming a ferrite layer on a surface of a thermoplastic substrate. The coated substrates are arranged such that the first ferrite layer contacts the second thermoplastic surface. Heating the layered assembly includes bonding the first coated substrate to the second coated substrate such that the first ferrite layer is sandwiched between a first thermoplastic substrate and a second thermoplastic substrate. The ferrite thin film laminate may include a multiplicity of coated substrates.

Some variations provide a magnetically anisotropic structure comprising a hexaferrite film disposed on a substrate, wherein the hexaferrite film contains a plurality of discrete and aligned magnetic hexaferrite particles, wherein the hexaferrite film is characterized by an average film thickness from about 1 micron to about 500 microns, and wherein the hexaferrite film contains less than 2 wt % organic matter. The hexaferrite film does not require a binder. Discrete particles are not sintered or annealed together because the maximum processing temperature to fabricate the structure is 500 C. or less, such as 250 C. or less. The magnetic hexaferrite particles may contain barium hexaferrite (BaFe.sub.12O.sub.19) and/or strontium hexaferrite (SrFe.sub.12O.sub.19). The hexaferrite film may be characterized by a remanence-to-saturation magnetization ratio of at least 0.7. Methods of making and using the magnetically anisotropic structure are also described.

Various embodiments of a magneto-acoustic spin-wave signal processing system are provided. In one embodiment, a system includes an acoustic wave transducer configured to produce surface acoustic waves in a plane of a magnetostrictive material, wherein the magnetostrictive material serves as a medium for spin waves traveling in the plane, and wherein the acoustic wave transducer is oriented such that the acoustic waves parametrically amplify the spin waves. In this way, signal processing systems achieve the benefits of both spin wave and acoustic wave devices, taking advantage of the low dispersion and high dynamic range of acoustic waves coupled with the tunability and nonlinear effects provided by spin waves.

Various embodiments of a magneto-acoustic spin-wave signal processing system are provided. In one embodiment, a system includes an acoustic wave transducer configured to produce surface acoustic waves in a plane of a magnetostrictive material, wherein the magnetostrictive material serves as a medium for spin waves traveling in the plane, and wherein the acoustic wave transducer is oriented such that the acoustic waves parametrically amplify the spin waves. In this way, signal processing systems achieve the benefits of both spin wave and acoustic wave devices, taking advantage of the low dispersion and high dynamic range of acoustic waves coupled with the tunability and nonlinear effects provided by spin waves.

A magnetic microcapsule, preparation method thereof and a magnetic film are disclosed, relating to microcapsule technology. The microcapsules use a combination of cationic and anionic polymers as the shell material, forming spindle-shaped, durable spheres to enhance strength. The core material contains at least two types of magnetic particles with different strengths, allowing adjustable magnetic forces to improve writing, erasure, and contrast. It also includes non-magnetic particles, an oil-based solvent, and a suspension stabilizer, forming a stable cross-linked network and electrostatic adsorption layer to prevent sedimentation and ensure smooth writing and lasting marks. The resulting magnetic film offers excellent responsiveness, enabling quick and thorough erasure by adjusting the magnetic pen's force and frequency.