NL9201561A - Polarizing filter as well as a method of manufacturing it. - Google Patents

Description

Polarizing filter as well as a method of manufacturing it.

The present invention relates to a polarization filter comprising a light-transmitting matrix with elongated electrically conductive particles arranged therein.

Such a polarization filter is described in the publication SPIE, vol. 1128, Glasses for opto-electronics, 1989, pp. 186 and beyond. It has been found that metal needles preferentially absorb the polarization component of light in line with the longitudinal axis of the particles. A signal-to-noise ratio between 500 and 10,000 is achievable here. The aforementioned publication describes only the use as a polarizing filter. This polarizing filter works only in a fixed direction and is not suitable for storing or displaying information.

The object of the invention is to provide a method with which it is possible to manufacture a polarization filter in a simple manner.

Moreover, it is the object of the present invention to provide a polarization filter with which it is possible to store information optically. After all, as stated above, a particularly large signal-to-noise ratio can be realized with polarizing flashes.

This object is achieved with a polarization filter described above in that the electrically conductive particles are magnetizable. Due to the magnetizable nature of the electrically conductive particles, they can be locally oriented differently by selectively applying a magnetic field. Therefore, information can be stored which can be read out later by means of the above-described effect.

It is noted that from the Philips Technical Magazine, volume 42, no. 2, March 1985 "Erasable magneto-optical recording" magneto-optical information carriers are known. It describes the use of a layer of material that changes properties when heated with, for example, a laser beam under the influence of an external magnetic field. By recording (freezing) these different magnetic properties, a pattern of domains magnetized in different directions is created. When irradiated with light (laser beam) of less intensity, they appear to have different optical properties. When reflecting on such a recording layer, due to the so-called Kerr effect, a polarization rotation takes place which depends on the magnetization direction of the respective domains. On the basis of this information can be stored and read.

The drawback of this information carrier is that the signal-to-noise ratio is relatively small.

The object of the present invention is to store information with the particles or to represent a certain state. The latter case concerns flat information carriers such as microfiches and LCDs in which the matrix is liquid under conditions of use and in which the particles are subjected to a selective magnetic field during use. By changing the direction of the magnetic field, another optical information can be written, which has been recorded after the matrix has solidified.

It is also possible to use a matrix which has solidified under conditions of use, but may melt by local heating, such as melting by a laser beam. Preferably this melting takes place over a short melting range. When locally melting the matrix material and subjecting it to a magnetic field, the particles present on site can be reoriented and after freezing such information can be stored and read out. For an optimum effect of both the orienting and the optical effect, the length / width ratio of the particles is preferably greater than 5. That is, the particles are of needle-shaped design. The particles may comprise any materials known in the art that are both magnetizable and conductive. Examples are iron, nematite and chromium oxide, which are known from the tape industry. It is also possible to design the particles as composite. The core can consist of a magnetic material and the exterior of the particles, which acts as an antenna, can consist of an electrically conductive material. Such a combination can be realized in all ways known in the prior art. According to an advantageous embodiment, the matrix comprises a film material in which the particles with the longitudinal dimension are arranged perpendicular to the film therein. By locally melting and reorienting certain domains of particles in the above manner using a light beam, information can then be stored. This is of particular importance with information carriers such as discs on which such a film is applied. Such a disc may optionally be provided with a growth pattern for guiding a laser head for either the input of information or the reading of information. It is of course also possible to design the information carrier as tape. In such a case, the basic direction of the particles is less important.

Although it is possible to manufacture the magnetic information carrier described above in any manner known in the art, it is preferred to subject it to a shearing force starting from a molten polymer into which the particles have been introduced by dissolution. As a result, the particles appear to be oriented. This orientation can be further enhanced by subjecting the magnetizable particles to a magnetic field at the location of the shear. This magnetic field must be applied in the direction of the shear and with a field strength greater than the coercive value of the magnetizable needle material. This also promotes the distribution of the magnetizable particles over the matrix material. The needles are less easily pulled together and move more easily over each other in the shear area. In order to realize a film material in which the orientation of the particles is perpendicular to the shear, it is preferred after the above treatment to subject the particles to a further magnetic field while the polymer is still in a liquid state, so that it is oriented perpendicularly on the shear direction. Combination of shear with a magnetic field can in particular be realized with a longitudinally magnetized shear beam. It is possible with the invention to return selectively oriented particles to the starting position by reheating the matrix and subjecting it to a selective magnetic field.

The only figure shows an example of a method for manufacturing a polarization film with a shear beam. The shear bar is indicated by 1 in it. N and Z stand for North Pole and South Pole respectively. In a manner not shown, a substrate 3 moves in the direction of arrow 2 on which a layer of material 4 is applied, consisting of a matrix with electrically conductive magnetizable parts arranged therein. When moving along the shear beam, shearing takes place on the one hand and orientation of the magnetic needles on the other hand. In this arrangement, the electrically conductive magnetizable elongated particles are oriented perpendicular to the surface.

It is possible after taking the polarization filter in this way to take no further steps, so that a polarization filter according to the prior art can be obtained in a particularly efficient manner. An example of this will be given below.

The polarizing effect of the matrix consisting of a polymer with iron needles arranged therein has been investigated. These iron needles were 30 nanometers in diameter and 300 nanometers in length. Needles of this type are available, inter alia, under the name Bayferroj® Magnetic materials from Bayer. These needles are placed in a PVC solution which is then dried. It was found that such iron needles could be oriented by applying them in a low concentration such as 0.3-2.3% in the liquid polymer, a solution of PVC in toluene, at a high shear rate. A value of 103-106 s'1 is mentioned as an example for the shear rate. This can be achieved with techniques well known in the art such as reverse roll, blade or slot coating techniques. It has been found that for good orientation and dispersion, the shear region should be as much times longer than the gap height as the length / diameter ratio of the needles. Orientation can be promoted by subjecting to a magnetic field.

In such a layer, before curing by evaporating the solvent, an information can be written by orienting the electrically conductive magnetizable needles via an external magnetic field. The orientation structure is then visible through the polarization-dependent absorption of the light.

It is also possible to save or change information at a later stage. In that case, it is necessary if the "frozen" orientation of the electrically conductive magnetizable particles is changed. This can be done, for example, by locally heating the matrix material with a heat source such as a laser beam or a hot needle and subjecting the electrically conductive magnetizable particles to a magnetic field. These particles will then reorient and "freeze" in the new orientation after the heat source has been removed.

Preferably matrix materials are used as listed in the attached table 1. These materials have a relatively short melting range at about 130 ° C. At or above this temperature, the needles can be oriented by a local external field. Due to the short melting range, the melting of the matrix can be limited to a small, precisely defined area.

Table 1

Supplier / producer

In order to properly control the process, it is important in writing and reading applications to use a polymer that has a particularly short melting range and more particularly a melting point.

Although the invention has been described above with reference to a special embodiment, it is to be understood that numerous modifications obvious to the skilled person can be made without going beyond the scope of the present application as described in the claims.

Claims (15)

Polarization filter comprising a light-transmitting matrix with elongated electrically conductive particles arranged therein, characterized in that the electrically conductive particles are magnetizable. Polarizing filter according to claim 1, wherein the matrix comprises a liquid material under conditions of use. Polarizing filter according to claim 1, wherein the matrix comprises a material solidified under conditions of use which has a relatively short melting range when heated. Polarizing filter according to any one of the preceding claims, wherein the length / width ratio of the electrically conductive particles is greater than 1. Polarizing filter according to any of the preceding claims, wherein the particles comprise a core magnetizable material and an outer layer of electrically conductive material. Polarizing filter according to any of the preceding claims, wherein the matrix comprises a film and wherein the particles are longitudinally sized perpendicular to the film therein. Tape comprising a polarizing filter according to any one of the preceding claims. Disc comprising a polarizing filter according to any one of claims 1-6. Disc according to claim 8, provided with a groove pattern. A method of manufacturing a magnetic optical polarization filter according to any one of claims 1 to 6, comprising dispersing particles in a liquid polymer and subjecting the mixture to a shear. The method of claim 10, wherein the particles are subjected to a magnetic field near the shear region. The method of claim 11, wherein the magnetic field is applied in the shear region. A method according to claim 11 or 12, wherein the magnetic field is oriented in the shear direction. The method of any one of claims 11-13, wherein the magnetic field comprises a plurality of subfields of different orientation, the particles being subjected first to a selective magnetic field according to claim 13 and then selectively to a magnetic field that the particles are perpendicular to that tends to orient. The method of any one of claims 11-13, wherein the matrix is melted locally and subjected there to a selective magnetic field which tends to orient the particles perpendicular to their original direction.