JP4491168B2 - Image forming method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image forming method and an image forming apparatus, and more particularly to an image forming method and an image forming apparatus for developing a magnetic latent image formed on a photoinduced magnetic material.
[0002]
[Prior art]
A method of forming a magnetic latent image on a magnetic recording medium, developing it with a magnetic toner to form a visible image, and transferring and fixing it on a recording paper to obtain a hard copy is called magnetography.
In this magnetography, when a latent image is recorded, a large number of copies can be made by repeating development and transfer.
Compared to the electrostatic system, it has advantages such as excellent environmental stability, little fluctuation in image quality, and ozone free. However, when a magnetic head is used, it lacks high speed.
When a multi-head is used, it is difficult to manufacture the multi-head with high accuracy. When thermomagnetic recording is used, high-speed recording is difficult and high energy is required.
On the other hand, there is known a method and an apparatus capable of preheating and thermomagnetic recording with a low-power laser beam such as a semiconductor laser by irradiating the recording medium with light (Japanese Patent Laid-Open No. 7-134436). Publication).
[0003]
On the other hand, as a photo-induced magnetic material, for example, a so-called III-V group diluted magnetic semiconductor in which a small amount of a magnetic element such as Mn is doped into a group III-V element is laminated with a group III-V semiconductor as required. [For example, the photoinduced magnetic material described in JP-A-11-203740, and the literature includes S.I. Koshihara, H .; Munekata et al. Phys. Rev. Lett. 78, 4617 (1997) etc.].
For example, ferromagnetism can be generated by laminating a thin film of InAs doped with Mn on GaSb and irradiating light at a temperature of 35K or lower.
[0004]
JP-A-7-134436 discloses a method of raising the temperature of a recording medium by irradiating light (heat mode) and forming a latent image on the recording medium thermomagnetically. There were problems with high speed and high resolution.
This problem can be solved by using a photo-induced magnetic material as a recording medium.
That is, by using a photo-induced magnetic material, a latent image can be formed by photon mode rather than heat mode by light irradiation.
However, since the above-mentioned photo-induced magnetic material has a very low temperature at which magnetization can be generated by irradiating light, in actual use, it is used in a limited state at a very low temperature, or a special refrigeration apparatus is used. The current situation is that it has a problem that it must be used.
Therefore, there has been a demand for an improvement in temperature at which magnetization can be generated by light irradiation.
[0005]
[Problems to be solved by the invention]
In view of such a current situation, the present invention can form a magnetic latent image in a font mode by light irradiation by using a photo-induced magnetic material, and can increase the resolution of the latent image at low speed with low energy. It is an object of the present invention to provide a forming method and an image forming apparatus.
[0006]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the present invention has been completed by focusing attention on the photo-induced magnetic material and as a result of intensive studies.
[0007]
That is, according to the present invention, first, a magnetic latent image is formed by irradiating light onto a photo-induced magnetic material capable of performing photo-induced magnetization by directly generating magnetization by light irradiation, An image forming method is provided that develops a magnetic latent image.
[0008]
According to the present invention, second, in an image forming apparatus having at least a magnetic recording medium, a magnetic latent image recording input unit, and a magnetic latent image developing unit, a photoinduced magnetic material is used for the magnetic recording medium. An image forming apparatus is provided.
[0009]
The second invention includes image forming apparatuses described in the following (i) to (viii).
(I) An image forming apparatus having a magnetic transfer medium for transferring the magnetic latent image.
(Ii) An image forming apparatus using a material containing at least a ferromagnetic material as the magnetic latent image developing means.
(Iii) The image forming apparatus in which the photoinduced magnetic material contains a magnetic semiconductor.
(Iv) The image forming apparatus in which the photoinduced magnetic material contains a diluted magnetic semiconductor.
(V) An image forming apparatus in which the photo-induced magnetic material contains a III-V diluted magnetic semiconductor.
(Vi) The image forming apparatus in which the photo-induced magnetic material contains a II-VI group diluted magnetic semiconductor.
(Vii) An image forming apparatus in which ferromagnetic particles are dispersed in the photoinduced magnetic material.
(viii) An image forming apparatus in which the ferromagnetic particles contain superparamagnetic particles.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described with reference to the drawings.
FIG. 1 is a conceptual diagram showing that the magnetic semiconductor matrix 1 is doped with a small amount of a magnetic element, and the magnetic spins 2 are directed in random directions, indicating paramagnetism.
When such a matrix material is irradiated with light of an appropriate wavelength, a large amount of carriers (electrons, holes, electron / hole pairs, etc.) are generated in the material, and the above-mentioned magnetic spins interact with these carriers. As a result, it is photoinduced magnetism that exhibits ferromagnetism.
[0011]
A conceptual diagram when this ferromagnetism is expressed is shown in FIG.
Here, it is also important that the carrier concentration before light irradiation is appropriately adjusted so as not to exhibit ferromagnetism.
In this way, the photo-induced magnetic material can transfer the magnetism of the material from, for example, paramagnetism to ferromagnetism (photon mode) by carriers generated by irradiating light, so that it is like a conventional magnetic material. In addition, compared with the magnetic transition (heat mode) due to temperature, the material is extremely useful in terms of energy and speed of switching the transition.
[0012]
FIG. 3 shows that a light-induced magnetic material is used as the magnetic recording medium, and a magnetic latent image is formed on the irradiated portion.
Only the portion irradiated with light is transferred to ferromagnetism, and a magnetic latent image is formed.
Since it is not the heat mode but the photon mode, switching can be performed at high speed and high resolution can be achieved.
FIG. 4 shows a pattern in which the magnetic latent image is developed using a developer containing a ferromagnetic material.
Here, it is necessary to use a ferromagnetic material having an appropriate magnetic characteristic with respect to the magnitude of the magnetization of the portion that has been changed to ferromagnetic when irradiated with light.
[0013]
If necessary, it may be used together with a pigment, and even if a magnetic toner is used, there is no problem as long as they have appropriate magnetic properties.
Needless to say, the appropriate magnetic properties referred to here differ depending on the type of the photo-induced magnetic material or the type of light to be irradiated.
Further, a hard copy can be obtained by transferring the developed image to paper as necessary and further fixing as necessary. Application as a magnetic printer is also possible.
[0014]
In the above, the case where development is performed on a photo-induced magnetic material that is a magnetic recording medium has been described. However, as shown in FIG. 5, the magnetic recording medium is formed on the magnetic recording medium by stacking the magnetic transfer medium separately from the magnetic recording medium. It is also possible to transfer the magnetic latent image to a magnetic transfer medium and develop it on the magnetic transfer medium as shown in FIG.
This makes it possible to separate the medium on which the magnetic latent image is to be formed and the medium to be developed, so that it is possible to select a suitable medium for each, and this is advantageous for image forming capability, high speed, and high resolution.
[0015]
Here, the conventional photo-induced magnetic material has a disadvantage that the temperature at which photo-induced magnetism can be generated is very low.
The present invention has also solved this drawback by dispersing ferromagnetic fine particles exhibiting superparamagnetism in a conventional photoinduced magnetic material.
FIG. 7 shows a conceptual diagram thereof.
When the volume of the ferromagnetic fine particles becomes extremely small, when the temperature rises, the thermal vibration energy becomes relatively large, and the magnetization of the ferromagnetic fine particles can be freely changed in direction. Apparently, it behaves like a paramagnetic material. This is called superparamagnetism.
In FIG. 7, ferromagnetic fine particles 7 having a volume sufficiently small to exhibit superparamagnetism are dispersed in a matrix doped with a small amount of a magnetic element, and the magnetic spin and magnetic moment of the material as a whole are random. It shows a good paramagnetism.
When this material is irradiated with light of an appropriate wavelength, a large amount of carriers (electrons, holes, electron-hole pairs, etc.) are generated in the material, and the above-mentioned magnetic spin and magnetic moment interact with this carrier. As a result, ferromagnetism is developed.
In this case, however, the temperature at which photo-induced magnetism is generated can be increased if fine particles that are originally ferromagnetic are dispersed and the Curie temperature of the fine particles has an appropriate value.
[0016]
FIG. 8 shows a conceptual diagram when ferromagnetism is manifested by this light irradiation.
As for the ferromagnetic fine particles to be dispersed, there is no problem even if it is not strictly a ferromagnetic fine particle, and ferrimagnetism or the like can also be used.
In this case as well, it is important to make the volume sufficiently small and exhibit superparamagnetism.
[0017]
As the matrix material, a semiconductor material is suitable because carriers need to be generated by irradiation with light.
Also, the semiconductor must be doped with a small amount of a magnetic element to such an extent that a ferromagnetic material does not precipitate or the matrix itself does not become a ferromagnetic material.
Therefore, a magnetic semiconductor is appropriate as the photoinduced magnetic material, and a diluted magnetic semiconductor is preferable in consideration of the doping amount of the magnetic element.
Furthermore, when considering the function as a photo-induced magnetic material, it is more preferable that the magnetic semiconductor is a group III-V diluted magnetic semiconductor or a group II-VI diluted magnetic semiconductor which has an advantage that carrier control can be widely performed.
[0018]
FIG. 9 shows that a magnetic latent image is formed in a portion irradiated with light using a photoinduced magnetic material in which ferromagnetic fine particles (superparamagnetism) are dispersed as a magnetic recording medium.
Only the portion irradiated with light is transferred to ferromagnetism, and a magnetic latent image is formed.
In this case, the magnetic latent image can be formed at a higher temperature.
Further, FIG. 10 shows a pattern in which the magnetic latent image is developed using a developer containing a ferromagnetic material.
As described above, development can be performed at a higher temperature. In this case as well, development can be performed after laminating magnetic transfer media and transferring the magnetic latent image.
[0019]
【Example】
EXAMPLES Hereinafter, although an Example is given and this invention is demonstrated in more detail, this invention is not limited at all by these Examples.
[0020]
Example 1
A buffer layer was laminated on the substrate, and a (InMn) As thin film in which InAs was doped with Mn was laminated.
The composition was (In _0.95 Mn _0.05 ) As, and a magnetic recording medium was prepared (Sample 1).
By irradiating the sample 1 with light, ferromagnetism could be developed, and a magnetic latent image could be formed in the irradiated portion.
By developing this with a developer containing a ferromagnetic material, an image could be formed.
[0021]
Example 2
As in Sample 1, a buffer layer is laminated on the substrate, and a layer in which MnAs fine particles (crystal grain size: 100 Å or less) are uniformly dispersed in the above (In _0.95 Mn _0.05 ) As is formed, and magnetic recording is performed. A medium (Sample 2) was obtained.
By irradiating samples 1 and 2 with light, both samples could exhibit ferromagnetism, and a magnetic latent image could be formed in the irradiated portion.
By developing this with a developer containing a ferromagnetic material, an image could be formed.
Assuming that the maximum temperatures at which magnetic latent images can be formed on the magnetic recording media of the respective samples are T1 and T2, respectively, T1 <T2, and by dispersing the ferromagnetic fine particles, the temperature at which the magnetic latent images are formed can be improved.
[0022]
Example 3
A buffer layer was laminated on the substrate, and a (GaMn) As thin film in which GaAs was doped with Mn was further laminated.
The composition was (Ga _0.97 Mn _0.03 ) As, and a magnetic recording medium was prepared (Sample 3).
By irradiating the sample 3 with light, ferromagnetism could be developed, and a magnetic latent image could be formed in the irradiated portion.
By developing this with a developer containing a ferromagnetic material, an image could be formed.
[0023]
Example 4
Similarly to Sample 3, a buffer layer is laminated on the substrate, and a layer in which GaMn fine particles (crystal grain size: 80 mm or less) are uniformly dispersed in the above (Ga _0.97 Mn _0.03 ) As is formed, and magnetic recording is performed. A medium (Sample 4) was obtained.
By irradiating samples 3 and 4 with light, both samples could exhibit ferromagnetism, and a magnetic latent image could be formed in the irradiated portion.
By developing this with a developer containing a ferromagnetic material, an image could be formed.
Assuming that the maximum temperatures at which magnetic latent images can be formed on the magnetic recording media of the respective samples are T3 and T4, respectively, T3 <T4. By dispersing the ferromagnetic fine particles, the temperature at which the magnetic latent images are formed can be improved.
[0024]
Example 5
In the same manner as in Example 3, a buffer layer was stacked on the substrate, and a (GaMn) As thin film in which GaAs was doped with Mn was stacked.
The composition was (Ga _0.97 Mn _0.03 ) As, and a magnetic recording medium was obtained.
Subsequently, this magnetic recording medium was laminated with a ferromagnetic magnetic transfer medium (Sample 5).
By irradiating the sample 5 with light from the opposite side of the magnetic transfer medium, ferromagnetism could be developed in the magnetic recording medium, and a magnetic latent image could be formed in the irradiated part.
The magnetic latent image could be transferred to a magnetic transfer medium.
An image could be formed by removing the transfer medium from Sample 5 and developing it with a developer containing a ferromagnetic material.
[0025]
Example 6
Similarly to Sample 4, a buffer layer is laminated on the substrate, and a layer in which GaMn fine particles (crystal grain size: 80 μm or less) are uniformly dispersed in (Ga _0.97 Mn _0.03 ) As is formed. did.
Subsequently, this magnetic recording medium was laminated with a ferromagnetic magnetic transfer medium (Sample 6).
By irradiating sample 5 and sample 6 with light from the opposite side of the magnetic transfer medium, both samples were able to exhibit ferromagnetism in the magnetic recording medium, and a magnetic latent image could be formed in the irradiated part. .
The magnetic latent image could be transferred to a magnetic transfer medium.
The transfer medium was removed from Sample 5 and Sample 6, respectively, and developed with a developer containing a ferromagnetic material, whereby an image could be formed.
When T5 and T6 are the maximum temperatures at which a magnetic latent image can be formed on the magnetic recording medium of each sample and transferred to the magnetic transfer medium, T5 <T6, and ferromagnetic fine particles are dispersed in the magnetic recording medium. The temperature at which images can be formed was improved.
[0026]
【The invention's effect】
According to the present invention, by using a photo-induced magnetic material, a magnetic latent image in a photon mode can be formed by light irradiation, and the latent image can be increased in resolution at high speed with low energy. A forming apparatus is provided and contributes greatly to the field of image formation.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram when a matrix doped with a small amount of a magnetic element shows paramagnetism.
FIG. 2 is a conceptual diagram when the matrix shows ferromagnetism by light irradiation.
FIG. 3 is a conceptual diagram showing that a magnetic latent image is formed by irradiating a magnetic recording medium with light.
FIG. 4 is a conceptual diagram showing that a magnetic latent image is developed with a developer containing a ferromagnetic material.
FIG. 5 is a conceptual diagram showing that a magnetic latent image of a magnetic recording medium is transferred to a magnetic transfer medium.
FIG. 6 is a conceptual diagram showing that a magnetic latent image on a magnetic transfer medium is developed with a developer containing a ferromagnetic material.
FIG. 7 is a conceptual diagram in the case where a matrix in which a small amount of magnetic element is doped and ferromagnetic fine particles are dispersed shows paramagnetism.
FIG. 8 is a conceptual diagram when the matrix shows ferromagnetism by light irradiation.
FIG. 9 is a conceptual diagram showing that a magnetic latent image is formed by irradiating light to a magnetic recording medium in which ferromagnetic fine particles are dispersed.
FIG. 10 is a conceptual diagram showing that a magnetic latent image is developed with a developer containing a ferromagnetic material.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Magnetic semiconductor matrix 2 Magnetic spin 3 Light irradiation 4 Magnetic recording medium 5 Developer containing ferromagnetic substance 6 Magnetic transfer medium 7 Ferromagnetic fine particle (the size which shows superparamagnetism)

Claims (1)

A light-induced magnetic material represented by (In _0.95 Mn _0.05 ) As or (Ga _0.97 Mn _0.03 ) As is irradiated with light to form a magnetic latent image, and the magnetic latent image is developed. Image forming method.

Images