DE1474337A1 - Recording material - Google Patents

Description

PATENT ADVERTISER DL HANS-GÜNTHER EGGERT, DIPLOMA CHEMIST

5 KDtN-LINDENTHAL PETER-KINTGEN-STRASSE 2

Cologne, December 6th, 1965 Eg / Ax

General EIectrio Company »

1 River Koad, Sohenectady 5 »N.Y * (V.St.A.)

Recording material

The invention relates to the recording of information, Data and images on thermoplastic polymer surfaces by deforming these surfaces and the subsequent reproduction or recovery of the recordings.

The invention is particularly directed to an improved recording material directed, comprising a layer of thermoplastic polymeric material formed according to a predetermined Pattern corresponding to a desired image can be electrostatically charged. After heating it is recorded Image as a pattern of small waves, grooves, or depressions in the surface of the thermoplastic layer through Application of heat reproduced or developed The image can be preserved or "frozen" by the thermoplastic Layer is then cooled »The information or other data recorded in this way can then reproduced at will from the "wave image" frozen on the surface of the thermoplastic layer or be regained. The improvement according to the invention is that a change in the surface of the thermoplastic Layer is made which greatly enhances the playback or recovery of the recorded images or data improved. crno V ■ '^ n · ■> · .., -

.309823 / 086 7

- ρ -

A recording device using an electron beam, using a solid recording medium with a thermoplastic surface layer, on which television pictures or other forms of data can be persistently recorded is disclosed in U.S.A. 3 113 179. This method is used to store digital data and analog data in forms other than in Applied in the form of a television picture «The storage of information in the form of a wave pattern developed by heat on the surface of a thermoplastic material can be achieved in other ways »For example is the use of photoconductors in connection with electromagnetic radiation in Belgian patent 612 described. The information, images or data recorded in this way can be played back or retrieved done in different ways. For example, optical devices with transmitted or reflected Radiation can be used. Direct copying by applying printing ink or the like to the raised ropes of the wave image and subsequent transfer of the printing ink to a sheet of paper is also possible · The application of electrostatic charged powders on the surface of the recording material using the residual electrostatic charges in the form of the original charge pattern has to Consequence that the powder depending on its electrostatic characteristics either to the areas that are still charged or to the areas that are free of charge, whereby either a positive or negative image is obtained which is either used directly or by known charge transfer methods can be transferred to another dielectric surface such as paper. Bach another applicable Method, the surface carrying the recording is scanned with an electron beam with formation a secondary electron emission which can be acquired and measured for data retrieval. This so-called wpunkt-. scanning "and the apparatus for performing this method

909823/086 7

are described in Italian patent 675 256 ·.

Generally there is this latter method of reproduction or recovery of data or messages in the fact that the surface of the thermoplastic layer containing the Information deformation contains, with a beam of primary electrons scanned, the secondary electrons captured by the Surface of the recording material as a result of the impact of the primary electron beam is emitted, and a measurement of the number of secondary captured Electrons as a yardstick for deriving the deformations recorded on the surface of the material When performing this procedure, a RÜokspielvorrichtung ("Playback") is used for recording, which consists of a cathode ray generation system that works with a Deflection device is provided which deflect the electron beam of the beam generator over a wide deflection angle capable · The beam generating system, is in a vacuum diohten Housing together with the solid, thermoplastic recording material, the recording of which is to be reproduced, held, with the jet generator and the surface of the recording material bearing the deformations facing each other Within the housing, a collecting device is arranged opposite the recording material so that they the primary electron beam doesn’t interfere · The catcher is used to catch secondary electrons from the Surface of the recording material are emitted as the pole of the impact of the primary electron beam. The in The secondary electron flow generated by the catching device then provides the tapping point for the recorded material on the recording material Message

There are certain problems with the reproduction method which uses the emission of secondary electrons. It is known that the concentration of the electron beam the easier and the point the smaller, the higher the speed

909823/0867

of the primary electrons, which gives greater resolution. The speed of these electrons is expressed in volts. As the speed of the primary electron beam increases, the number of secondary electrons emitted from the thermoplastic recording surface increases in a curvilinear relationship until, at a first voltage, the ratio of the number of incident or primary electrons to the number of emitted or secondary electrons is 1: 1. This can be referred to as the "first crossing point ^11. As the speed of the primary electrons increases further, the ratio of emitted electrons to impinging electrons increases up to a maximum and then drops to a point at which the ratio is again 1: 1. This has been referred to as the »second crossing point ^11. A further increase in the speed of the primary electron beam results in a progressively lower number of secondary electrons. When the speed of the primary electrons is between the first and second crossing point, a positive charge will be seen on the thermoplastic The presence of a positive or negative charge on the surface of the recording material is undesirable This is important because it affects the focus of the beam and the position of the point and at the same time deflects the path of the secondary electrons. In order to operate such an apparatus with the greatest possible efficiency, the speed of the primary electrons must be kept at a voltage that corresponds to the second point of intersection of the material to be scanned is practically identical. The voltage of the second crossing point for thermoplastic polymers which are suitable for recording materials of the type described here is in the order of magnitude of 1000-1500 V. It would be expedient to use the reproducing apparatus with primary electron velocities of 5000 V or more

"09823/0867

"Operate. It is known that by reducing the angle of incidence of the primary electron beam onto the recording surface from 90 ° to 45 ° the effective speed of the second crossing point can be increased significantly, however the increased voltage is still below the desired voltage range.

Working at these higher voltages has the following advantages: Better bundling and consequently smaller size dea sampling point, which achieves better resolution and therefore the use of a greater storage density in the recording material becomes possible, and higher playback speed.

If, with today's methods, reproduction is by optical reflection, a highly reflective layer or mirror layer is placed on a substrate and a layer of a practically transparent, deformable, thermoplastic polymer is applied to the mirror layer. After the information to be recorded has been frozen in the recording layer in a wave or groove pattern, reproduction is carried out by reflection by allowing a light beam to pass through the recording layer and observing changes in the light reflected by the mirror layer pass through the recording layer, as a result of which the achievable resolution deteriorates and © is obtained with a low signal-to-noise ratio or a low ratio of useful to interference level and the light beam is impaired by a deterioration in the transparency of the recording layer, which can occur due to alternate heating and cooling, leading to erasure and it is necessary to reuse the recording material. It is therefore desirable to eliminate the disadvantages resulting from the fact that the light beam has to pass through the transparent layer twice in order to generate a usable signal rden.

The invention relates to an improved solid, thermally deformable polymeric recording material with a recording surface that allows more efficient reproduction or recovery of information and data stored thereon enables the recording material according to the invention, on a layer support a layer of a thermoplastic organic material with a deformable Has surface, is characterized in that there is a thin film that is in all directions is essentially electrically non-conductive parallel to the surface ο

The thin film is continuous and consists of an electrically non-conductive or at best only semiconducting one Material that increases the stress of the second crossing point the secondary electron emission of the thermoplastic material by at least $ 50 without the ability the thermoplastic recording layer to absorb and retain an electrical charge and thermally To form wave or groove patterns according to the charge image, significantly impairing. In addition, with these coated recording materials when using a working with reflected or transmitted rays optical reproduction system increased spectral reflectivity and usable permeability achieved *

It has been found that similar coatings increase the sensitivity to deformation of the thermoplastic coating layer, as described in the German patent ... _β ..... (patent application ......).

In previous attempts to change the recording surface of these thermoplastic recording materials, was found that the surface's ability to be electrostatic Picking up and holding charge is greatly reduced or has been eliminated. Furthermore, it was possible to load • Recording materials whose ability to heat © under

Π09823 / 08Β7

Formation of an image made up of waves or grooves to address, largely reduced

However, it has been found that when using materials which can be vapor-deposited onto the recording surface in the form of tiny islands instead of a closed elm, rather thick films deposited on the recording surface that are non-electrically conductive, even if the materials as such are electrical conductors · The reason for this phenomenon is seen in the fact that certain Materials have the tendency to move from the vapor state to particles of the already precipitated Knocking down material or walking towards you instead of sitting directly on the surface. These materials . thus tend to - agglomerate with the formation of tiny islands of increasing thickness, which are probably physically separated from neighboring deposition sites · Films made of vapor-deposited metals such as tin, germanium, indium and silver, behave in this way · Many more metals can act in this way as agglomerated structures precipitated by using low evaporation rates or by heating the substrate. Vaporizable non-metallic materials such as zinc sulfide can also be applied in this manner.

example 1

A thermoplastic recording layer of 30 η thick was prepared by pouring a solution of a polystyrene having an average molecular weight of 20,000 dissolved in a solvent mixture consisting of benzene, toluene and xylene onto glass sheets of 5 × 5 μm and evaporating the solvent _β Das The reflectance of the polystyrene recording surface was measured across the visible spectrum and found to be about $ 10

^Λ C 9 8 2 3 / Π 8 ft 7

Pressure of 10 "* ⁴ " mm Hg was evacuated · As a result, a thin film 100 µ thick was deposited. The reflectivity of the coated surface was measured. It corresponded to that of a mirror. The reflection was at a wavelength of 400 mu 64 #, at 500 m »68 #, at 600 mn 72 # and at 700 mu 72? Ί. The resistance, drawn on the 1 megohm scale of an ohmmeter, was infinite. The film formed an electrically interrupted layer with high spectral reflectance. The underlying recording layer assumed an electrostatic charge and could be thermally deformed according to the charge. The permeability of the material was measured over the range of the visible spectrum. It was Qfi at 400 mu and decreased almost linearly to 4.5 # at 700 mu .

Example 2

Lasers coated with polystyrene were applied to those in Example 1 - Manufactured in the manner described and in the same manner with interrupted, 100 8th thick coatings of tin, zinc sulfide and silver. The emission of secondary electrons was for these glasses as well as for a glass with an uncoated one Polystyrene film must be applied to their respective crossover points for secondary electrons at an angle of incidence of the electron beam of 90 °, i.e. perpendicular to the surface, to determine.

material Crossover position for Secondary electrons Uncoated polystyrene 1300 V tin 3200 Y Zinc sulfide 5100 T silver 2260 7

Because by reducing the angle of incidence of the electron beam from 90 ° to 45-60 °, as is well known, the second crossover stresses of these materials increase by 100? 4,

909823/0867

can be, these materials in voltage ranges Use between 500Ö and 10,000 V As previously impaired these coatings do not have the ability of the polymeric material to “take up and retain an electrostatic charge or deform in response to it. They were charged with 1000 V direct current. By heating a deformation image was developed that could be reproduced.

Using known optical reproduction methods, the thickness of the mirror film can advantageously be reduced so that the amount of light transmitted can be increased, whereby reproduction is possible by means of both reflected and transmitted radiation one method, the information obtained is checked against the information obtained by the other method at the same time · The upper limit for the thickness of such mirror films is 150% · Above this value the transmittance decreases to a point at which the film becomes unusable «Films a thickness of about 10-20 % can be used, but as the thickness approaches 300 % the ability of the underlying thermoplastic layer to deform is impaired,

One of the major advantages of the highly reflective surface for optical reproduction is that the top surface is used to reflect the signal · This enables higher efficiency and higher resolution, because the signal is not duroh particles or other light scattering Defects in the thermoplastic film or in the substrate is impaired.

In addition to the materials mentioned in the examples, also other metals and compounds beneficial to the formation of the deposited surface film can be used For example, gold behaves very similarly to that

909823/0867

- TG -

Tin, when it forms agglomerated precipitates in thin films and not a closed film, and its secondary crossover point is above 2000 V. Chemical compounds that have desirable properties are the alkali halides, e.g. KBr, KCl ₉ KJ, NaBr and NaCl, as well as oxides, such as BeO and MgO _β It will be understood that only in cases where the material of the uppermost film is electrically conductive as such is there a need for the films to consist of interrupted islands. When the film is formed of practically non-conductive material , practically closed films can be used

According to the above description, the applied surface films are formed by vapor deposition of the respective Materials and condensation of vapors on the surface of the thermoplastic. Document. However, it is also possible apply equivalent films using other methods, ζ · Β. duroh vapor phase reactions, atomization, electrodeless plating, fluidized bed processes and others.

9098 23/086

Claims (7)

r 11 - .- 1Α74337 Claims (1. ) J recording material consisting of a layer of thermoplastic organic material on a carrier with a deformable surface, characterized by a thin film applied to the layer of thermoplastic material which is essentially electrically non-conductive in all directions parallel to its surface. 2.) Recording material according to claim 1, characterized in that that the thin film consists of vapor-deposited material. j.) recording material according to claim 1 and 2, characterized characterized in that the thin film has a second cross point of secondary electron emission greater than 2000 V when the recording material hits the deformable surface at an angle of 90 ° incident electron beam is exposed. 4.) Recording material according to claim 1 to] 5, characterized characterized in that the thickness of the film is less than 300 8, preferably 10 to JOO 8. 5 ·) recording material according to claim 1 to 4, characterized characterized in that the film consists of individual agglomerated islands. 6.) Recording material according to claim 1 to 5, characterized characterized in that the film is optically specular and transparent. · 7.) Process for the production of a recording material according to claim 1 to 6, characterized in that one a layer of a thermoplastic recording material is applied to a support and to the surface of the thermoplastic layer an electrically non-conductive film in the form of individual agglomerated islands precipitates from the vapor phase. 909823/0567