NO133857B - - Google Patents

Description

Light control cell.

The present invention relates to a light control cell which can be controlled by an electric field and comprises a liquid crystal, which is arranged between two plates and consists of a substance which has a nematic phase and positive dielectric anisotropy, whereby at least one of the plates is transparent to light .

There are known optical devices which make use of the so-called "dynamic scattering" effect (D.S.), see e.g. British Patent No. 1,167,486. These devices are essentially a capacitor with light-permeable plates, whose dielectric is formed by a nematic substance. An electric current passes through this capacitor, whose moving charge carriers induce turbulence in the nematic substance. As nematic substances are optically anisotropic, light falling through the transparent capacitor plates on the liquid crystal will be scattered as a result of the turbulence. This changes the translucency of the cell or reflection.

Optical cells that make use of the "dynamic scattering" effect cannot be used if high demands are placed on the optical homogeneity of the cells, because the liquid turbulences will interfere in such cases. Another disadvantage is that the coherence and polarization of the incident light is lost due to the scattering process, so that e.g. laser light cannot be modulated using a D.S. cell without these properties being destroyed. For many purposes where small dimensions of the power supply parts are required, e.g. with battery operation, the high voltage threshold of approx. 6 volts and the similarly high voltage of 20 volts for saturation of the light spread be unfortunate. Finally, the lifetime is probably greatly affected by the ion transport through it

nematic substance (the higher the current through the cell, the shorter the cell's lifetime).

The invention aims to circumvent the aforementioned disadvantages. The invention is thus based on the task of providing a light control cell which is optically homogeneous and where the coherence and polarization of the incident light is maintained.

According to the invention, this is achieved by a light control cell of the type mentioned at the outset, where the liquid crystal has a helical structure with a view to a direction extending perpendicular to the plates, where the plates have a surface quality that orients the adjacent molecules of the liquid crystal in a preferred direction, and where in front of and behind the liquid crystal, seen in the direction of the incident light, a separate polarizer is arranged.

The so-called wall orientation of the plates thus consists of a specific surface ebeskaf f unit which exerts an orienting directional force on the molecules closest to the plate, i.e. on the boundary layer of the liquid crystal. The molecules in the boundary layer line up parallel to the wall orientation. As is known, the wall orientation is achieved, for example, by rubbing the plate surface with a cotton ball or stick. The liquid crystal consists of e.g. of a nematic compound. Nematic liquid crystals have a parallel structure, i.e. the molecules are in an unaffected state essentially parallel oriented in a preferred direction.

When a nematic liquid crystal is located between two plates

with rectified wall orientation, the crystal structure will assume a preferred direction, parallel to the wall orientation. If the two plates are rotated relative to each other, the boundary layers will follow the plate surfaces. Between the boundary layers, the nematic molecules will be oriented so that a continuous transition is formed from one direction of the wall orientation to another. When looking at the orientation of the nematic molecules along an elect-

free perpendicular to the plates, a screw-shaped device appears

nothing.

A helical structure of this type can also be achieved by

the nematic liquid crystal is mixed with a small amount of cholesteric, crystalline liquid or other optically active substance. < Cholesteric liquid crystals have a helical structure

in an unaffected state. By adding such crystals to the nematic liquid crystal, the helical structure is induced in it, so to speak. In the case of the wall orientation, respectively by the resulting adhesion, the screw structure is fixed to the plate-over tracks.

A liquid crystal with a helical structure is optically active,

i.e. that the polarization direction of continuous, linearly polarized light follows the helical winding of the crystal structure.

For liquid crystals with positive dielectric anisotropy is

the optical activity controllable by an electric field. When a sufficiently strong electric field is induced in the liquid crystal

risk field in the direction of the screw axis (i.e. perpendicular to the plates), the molecules, apart from the molecules in the adhering boundary layer, will arrange themselves parallel to the field. Thereby, the screw structure is destroyed and the optical activity is lost. After switching off the field, the previous structure will reappear.

Further features and advantageous details of the invention will be apparent from the following description of exemplary embodiments shown in the drawing. Fig. 1 shows a model of a liquid crystal with a helical structure. Fig. 2 shows an electro-optical device with continuously controllable transmission. Fig. 3 reproduces a graphic diagram of the transmission for a cell according to the invention as a function of the voltage on the plates. Fig. 4 reproduces a graphic diagram of the angle of rotation for the device shown in fig. 2 depending on the voltage.

In fig. 1, the orientation of different layers in a liquid crystal with a helical structure is schematically represented. The present screw structure can either be induced by means of the wall orientation of two plates (not shown), between which the liquid crystal lies, or by mixing in cholesteric compounds. Boundary layer 1 is oriented in the y direction, while boundary layer 2 is oriented in the z direction. In an optional plane 3 between the boundary layers, one has an orientation in the direction of an angle that lies between the y and z orientation. The angle depends on the distance to the boundary layers.

The electro-optical device for continuous control of the transmission shown in fig. 2, consists of an electro-optical cell 11, which is arranged between a polarizer 12 and an analyzer 13 running parallel to this. The cell 11 has the shape of a plate capacitor and is consequently made up of two plates or electrodes 14,15 which are arranged plane parallel at a distance from each other, and an intermediate dielectric 16.

This dielectric 16 consists of a nematic, liquid crystal with positive dielectric anisotropy (ie the dielectric constant along the longitudinal axis of the molecules is greater than the dielectric constant in the direction perpendicular to this £jj? ).

The two electrodes 14,15 consist of glass plates. The surfaces of the electrodes facing the liquid crystal are coated with SnC^. The Sn02 surfaces are treated so that the liquid crystal molecules in the boundary layer orient themselves with their longitudinal axes parallel to the electrode surface in a preferred direction.

In the composite cell 11, the preferred directions of the two electrodes 14,15 are mutually distorted. The molecules of the liquid crystal align in the boundary layers according to the preferred directions of the electrodes. Meanwhile, the nematic molecules are orien-

tert so that a continuous transition is formed from the preferred direction in the boundary layer towards the electrode 14 to the preferred direction in the boundary layer towards the electrode 15. When one looks at the orientation of the liquid crystal's molecules along an optional perpendicular to the electrodes, a helically turned device appears.

It has been shown that the polarization direction of light such as

falls in through the electrode 14 and is linearly polarized parallel to its preferred direction, follows the orientation of the nematic molecules. When the light leaves the cell 11 through the second electrode 15, it coincides with its preferred direction. When the preferred directions of the electrodes 14 and 15

are mutually offset by 90° (crossed wall orientation), the polarization direction of the incident light is rotated by 90°.

The cell 11 is thus located between the polarizer 12 and the analyzer

13 that the preferred direction of the electrode 14 which is

running close to the polarizer 12, is parallel to the polarization direction of the polarizer 12. At the intersection of wall orientation in cell 11

the preferred direction of the electrode 15 will therefore run perpendicular to the polarization direction of the analyzer 13. Light falling through the polarizer 12 from a light source 17, polari-

is thus seen in the direction of the z-coordinate shown, enters a liquid crystal 16 through the electrode 14, turns on its path through the crystal 16 continuously in the y direction, leaves

ter the cell 11 through the electrode 15 and is not passed through the analyzer 13 which is oriented in the z direction. An observer 18 will thus not see light from the light source 17.

When, on the other hand, the analyzer 18 is rotated 90° to the polarizer 12, the light from the light source 17 reaches the observer 18.

If electrodes 14 and 15 are energized and thus

If an electric field is formed in the liquid crystal that is perpendicular to the electrodes, the nematic molecules will be affected by a torque due to feji € «L, which seeks to align the molecules' longitudinal axes in the direction of the field. With increasing voltage on the electrodes, the orientation will more and more approach the direction of the field vector, until at a sufficiently high voltage it is practically parallel to the field vector. At the same time, the liquid crystal's helical structure and thus its optical activity will almost completely disappear. Polarized light falling in through the electrode 14 leaves the cell 11 with the direction of polarization unchanged. After switching off the voltage, the liquid crystal's helical structure will be restored due to the wall orientation.

If the electrodes for the mentioned device according to fig. 1, where the polarization directions of the polarizer 12 and the analyzer 13 are parallel, is put under voltage, the polarized light, depending on the strength of the voltage, will be completely or partially released to the observer 18. In the case when the polarizer and the analyzer are crossed, a sufficiently strong voltage will cause that no light reaches the observer 18 from the light source 17.

Fig. 3 shows the mentioned device's transmission with parallel polarization direction of polarizer and analyzer, depending on the voltage on the electrodes. It can be seen that the transmission without voltage is approximately 0. With rising voltage, it first remains at this level, until a voltage threshold conditioned by polarization phenomena. Above this voltage threshold, the transmission shows a continuous increase and eventually reaches a kind of saturation.

The optical activity can be controlled with direct voltage or alternating voltage. The preferred mode of operation depends on the intended use. Because polarization phenomena are avoided, the voltage threshold is particularly low in alternating voltage operation. The course of the curve in fig.

2 is frequency independent up to approx. 80 khz.

In the device mentioned, N(4'-ethoxybenzylidene)-4-aminobenzonitrile (PEBAB) was used as liquid crystal. It will be obvious that any other nematic substance with positive anisotropy

fi, i.e. with £,A» ^-an is used with essentially the same result. The electrode rafts in the mentioned cell are approx. 4 cm^.

The liquid crystal has a thickness of 10-100 my.

The following results that have been achieved with the mentioned device vi-

clearly sees the advantages of a cell according to the invention together

similar to a corresponding electro-optical cell, which is based on the "dynamic scattering" effect.

The polarization of the incident light remains practically unchanged, so that cells according to the invention e.g. also suitable for modulation of laser light. The voltage threshold for actu-

that of the electro-optic effect is approx. 1 v for alternating voltage

ning and approx. 2.5 v for direct voltage. The saturation voltage is approx.

4 v for direct and alternating voltage. The power consumption is significantly lower with direct voltage operation than with D.S. cells. Finally, the lifetime is very long due to the low charge carrier trans-

gate.

With a large number of possible modifications, different beneficial effects can be achieved. Thus, it can e.g. by using a colored liquid crystal in the cell 11 together with two polarizers, a device is provided which is impermeable to light without voltage and only allows one color to pass through when voltage is applied. The reverse relationship can also be realised. In the transition area, corresponding shadings are achieved between black and the selected colour.

The cell 11 can also be operated for reflection. For this purpose, the

the analyzer 13 (e.g. in the form of a foil), which is arranged behind the cell, is placed on an ordinary mirror. The incident light will either be reflected or absorbed on the mirror depending on the voltage.

Due to its properties, the cell according to the invention is suitable

for diverse applications. An application based on

the property of coherence is maintained, consists in the cell being used as an element in a page registration matrix for registration in a hologram memory. As is known, such a matrix consists of a large number (e.g. 10 4 ) of elements which, depending on the control, block coherent light or let it through and thus serve to register a Bit in the memory. Special

is a device possible that allows addressing. For this purpose, the liquid crystal is placed between two plates, the conductive coating of which is divided into a number of mutually insulated strips, so that the strip directions for the two plates run perpendicular to each other. With the help of suitable connections, the strips can be placed under tension, so that the addressing of the individual segments becomes possible.

Apart from this particular application, the cells are generally suitable for modulating the light intensity. Here, the low control voltages are particularly advantageous.

As the light beam can be extinguished, unlike what is the case with D.S. cells, it is possible to manufacture electro-optical locks. One can likewise achieve electronic control and modulation in the direction of the plane of polarization of linearly polarized light (e.g. polarimetry). Further areas of application are remote vision technology and data processing (registration of optical and electrical signals).

Another possibility lies in the production of spectacle lenses whose absorption is controlled by the intensity of the incident light.

Claims (14)

1. Light control cell that can be controlled by an electric field and comprises a liquid crystal, which is arranged between two plates and consists of a substance, which has a nematic phase and positive dielectric anisotropy, whereby at least one of the plates is transparent to light, characterized in that the liquid crystal has a helical structure with a view to a direction extending perpendicular to the plates (14, 15), that the plates have a surface quality that orients the adjacent molecules of the liquid crystal in a preferred direction and that in front and behind the liquid crystal, seen in direction of the incident light, a separate polarizer is arranged. 2. Light control cell as stated in claim 1, characterized in that the liquid crystal (16) contains an optically active substance. 3. Light control cell as stated in claim 2, characterized in that the optically active substance contains a cholesteric compound. 4. Light control cell as stated in one of the preceding claims, characterized in that the directions of the orientation effect of the two plates run perpendicular to each other. 5. Light control cell as specified in one of the preceding claims, characterized in that the pitch of the liquid crystal's (16) screw structure is greater than the plate spacing. 6. Light control cell as specified in claim 5, characterized in that the pitch is four times the plate distance. 7. Light control cell as specified in one of the preceding claims, characterized in that the plates have an electrically conductive layer and that connection lines are arranged so that lde electrically conductive layer can be put under voltage. 8. Light control cell as specified in claim 4, characterized in that the two polarizers are parallel oriented. — 9. Light control cell as specified in claim 4, characterized in that the two polarizers are crossed. 10. Light control cell as specified in claim 7, characterized in that the electrically conductive layers consist of surfaces isolated from each other. 11. Light control cell as specified in claim 10, grade i- — characterized in that the surfaces are parallel stripes. 12. Light control cell as specified in claim 11, characterized in that the strip direction on the two plates is at right angles to each other. 13. Light control cell as stated in claim 7, characterized in that the mentioned voltage is a direct voltage. 14. Light control cell as stated in claim 7, characterized in that the mentioned voltage is an alternating voltage.