DE2707296A1 - IMAGE DISPLAY DEVICE CONTAINING A LAYER OF NEMATIC LIQUID CRYSTAL - Google Patents

Description

Image display device comprising a layer of a Contains nematic liquid crystal.

The invention relates to an image display device comprising a layer of a nematic liquid crystal with positive dielectric anisotropy

Contains means for applying an electric field perpendicular to the layer and means with their A preferential orientation of the molecules of the liquid crystal parallel to the layer helps in the fieldless state is brought about.

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PHN. 8317. 4.1.77.

Image display devices comprising a liquid crystal are passive, i.e. devices that do not generate light themselves for reproducing images, and in particular to display alphanumeric and other symbols. They are used, for example, in measuring instruments, watches and pocket calculators used and generally have the favorable property that their energy consumption is relatively low. With regard to the applications mentioned, the Observer generally on the same side of the device as the light source (generally the ambient light) which means that the device is in the reflux mode have to work.

In the article "VoItage-dejendent optical activity of a twisted nematic liquid crystal" in "Applied Physics Letters", Volume 18, No. h , February 15, 1971, pp 127-128, it is described that a nematic liquid crystal with a positive dielectric anisotropy, ie that the dielectric constant parallel to the longitudinal direction of the elongated molecules is greater than perpendicular to this direction, can be provided with a planar texture rotated over 90 °. This texture has the property that the polarization direction of polarized light is rotated through 90 °. An electric field perpendicular to the liquid crystal layer makes this texture disappear because the molecules then align themselves in the

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Correlation with <■ I / ^ ^ / perpendicular to the layer, whereby polarized light is then no longer influenced. By arranging such a device between polarization boxes, the passage of light can be controlled by means of electrical voltages.

When such a device operates in the reflective mode, the light must pass each polarizer twice happen. As practical polarizers also have a proportionate effect have high absorption of light polarized in the direction of transmission of the polarizer, practice them has a very unfavorable influence on the highest possible intensity. Under intensity is in this context understand the amount of reflected light.

The invention aims to achieve the intensity that can be achieved with image display devices of the type mentioned can be to enlarge.

Another object of the invention is the use of polarizers in such image display devices to avoid.

According to the invention of the type mentioned in the first paragraph is dissolved in the liquid crystal, a dichroic dye and provide the device with means to an image reproduction device, with the aid of the liquid crystal layer, transmitted light having a 90 ° rotated polarizing direction reflects λ is.

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A dichroic dye has the property that it only absorbs light with a polarization direction parallel to the longitudinal direction of the elongated molecules, but light with other polarization directions is transmitted. The molecules of the dichroic dye further take on the orientation of the molecules of the liquid crystal in which they are dissolved. This has the consequence that in the non-excited state due to the rotation of the polarization direction of the reflected light via QO ⁰ all light is absorbed either on the way there or on the way back (after reflection). No light is absorbed when excited.

The means by which the light is reflected with a polarization direction rotated by more than 90 ° preferably consist of a % ? ₍ Retardation plate and a reflective layer, the main optical directions of this £ ^ -plate enclose an angle of almost 45 ° with the preferred orientation of the liquid crystal on the side of the £ ^ -plate.

A £ λ retardation plate is to be understood here as a plate made of a birefringent material which has such a thickness that the component of light with the wavelength / \, which is polarized in one of the main optical directions of the plate, has a phase shift of £ 7 \ (or an odd multiple of ^ - 7 \ )

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with respect to those in the other main optical direction polarized component receives.

It should be noted that the use of a dichroic dye, yellow in a cholesteric liquid crystal, from the article "New absorptive mode i'eflectivc liquid-crystal display device" in "Journal of Applied Physics" h5, November 1 97> \ , p. ^ 7i8 - / »723 is known. The image display devices described in this article, however, require a relatively high switching voltage.

Means with the help of which with a polarization direction rotated by more than 90 ° from a liquid crystal layer Transmitted light is wildly reflected from an enlarging plate and a reflective layer exist are known per se from the Dutch patent application 7 ^ 1 6 5 ^ 0. In this patent application but an imaging device has been described in which, in the non-excited state, the layer of nctnatic liquid crystal should have a structure twisted over ^ 5 °, while further the device on the side of the observer should be provided with a polarizer.

The invention is explained in more detail below, for example with reference to the drawing. Show it:

1 and 2 an explanation of the principle of the invention, and

Fig. 3 shows an embodiment of an image display

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device according to the invention.

1 and 2 schematically show a layer of a magnetic liquid crystal 1 with positive dielectric anisotropy in which a dichroic dye is dissolved, a retardation plate 2 and a layer 3. The optical main directions the J ^ -verzofjcxuiigsplatto are indicated by the arrows U and ^r and form an angle of 15 ° with the horizontal and vertical planes. The plate 2 has such a thickness and such an optical anisotropy that the component of light with the wavelength t \ , which is polarized in the direction of the arrow h , has a phase shift of \ T \ (or possibly an odd multiple of τ; 7 ^ ) with respect to the component polarized in the direction of arrow 5.

In FIG. 1, no electric field occurs over the layer 1. The preferred orientation of the elongated Molecules of the liquid crystal is perpendicular as indicated schematically.

In FIG. 2, an electric field perpendicular to the layer 1 is present. Since there is 2. \ j S & J_ of the liquid crystal, the elongated molecules of the liquid crystal align themselves parallel to the electric field, that is to say horizontally, as indicated schematically.

The elongated molecules of the dichroic dye take the direction of the molecules of the liquid

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crystals and are a J-so in Fig. 1 also perpendicular and in Fig. 2 also horizontally.

Of unpolarized light that hits layer 1 in FIG. 1, all components with a perpendicular polarization direction are absorbed by the perpendicularly directed molecules of the dichroic dye, so that the light on the way out between layer 1 and plate 2 is horizontal is polarized. The component of this light with a polarization direction according to the arrow h receives a phase shift of J "7i with respect to the component with a polarization direction according to the arrow 3 through the passage through the plate 2, reflection at the layer 3 and another sag through the plate 2 On the way back, the light is then polarized perpendicularly between plate 2 and layer 1 and is absorbed by the dichroic dye in layer 1. It should be noted that the light between plate 2 and layer 3 is circularly polarized, where the direction of the circular polarization (seen in the direction of propagation of the light) is reversed by the reflection at the layer 3. It thus turns out that in the non-excited state (no electric field above the layer 1) all light is absorbed by the layer 1 .

Unpolarized light that hits the layer in Fig. 2 is transmitted unimpeded and remains, too

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after two passes through plate 2, unpolarized, because all directions of polarization are present. It shows thus that in the excited state (an electric field perpendicular to the layer) all light from the layer 1 is let through.

Since there is no effect at all for the above-described effect

Polarizers are required, parasitic absorption of light in the excited state is almost completely avoided and a very high intensity is obtained in the excited state. FIG. 3 shows the construction of an image display device which is based on the principle explained with reference to FIGS. 1 and 2. The device contains a glass front plate 6 and a glass rear plate 7, which are held at a mutual distance of 20 μm and are sealed 15 'on the circumference by a polyethylene seal 8. The plates 6 and 7 have a thickness of 2 mm and are provided with transparent tin oxide electrodes 9, 10, 11 and 12 on the mutually facing sides. The electrodes 9, 10 and 11 can, for example, belong to a set of seven electrodes which are arranged in the form of a stylized figure eight in order to be able to reproduce the figures from zero to nine in a known manner. Between the plates 6 and 7 there is a layer 15 of a nematic liquid crystal with positive dielectric anisotropy in which a dichroic dye is dissolved.

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/ IA

On the back plate 7 there is another one -Delay plate 13i which is about 25 Aim thick and made of

Ordered mica. A reflective aluminum mirror is steamed for 1 hour on the delay plate 13. In FIG. 1, it is assumed that there is a voltage difference between the electrode 10 and the electrode 12, which is evident from the schematically indicated alignment of the liquid crystal Is.

In the non-excited state, e.g. between electrodes 9 and 12 or 11 and 12, the tension orientation of the molecules of the liquid crystal is parallel to the support plates and, in a layer adjacent to the plate 7, forms an angle of Ί5 ⁰ with the main optical directions of the τ} Λ -Delay plate 13. In a layer adjoining the plate 6, the preferred orientation of the molecules of the liquid crystal can have the same or a different direction. If the direction of the plate 6 is different from that of the plate 7, the liquid crystal is so-called "twisted", which means that the orientation of the molecules, from one plate to the other, gradually rotates. Such a twist has the property that the polarization direction of light follows the rotation of the twist. Since the molecules of the dichroic dye also follow the rotation of the twist that may be present, takes place

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the absorption of light with a certain direction of polarization takes place in exactly the same way as if none Twist would be present. Thus, only the preferred orientation is on the side of the plate 7 for the direction the main optical directions of the plate 13 are decisive.

A preferred orientation can be obtained in a known manner in that the plates 6 and 7 with e.g. Paper used to clean lenses is rubbed in a specific direction.

Suitable liquid crystals and dichroic dyes for use in a device according to the invention are known from the prior art. A suitable nematic liquid crystal having U ^ ^ ^ J.und a suitable nematic temperature range is for example a mixture in a molar ratio of 2: 1 of k '-Cyanophenyl - ^ - n-heptylbenzoat and h' -Cyanophenyl - ^ - nbutylbenzoat. A suitable dichroic dye is, for example, 1- (5-nitro-2-thiazolylazo) -phenyl-4-N-pyrolidine.

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Examples of other liquid crystals that

can be used in a device according to the invention are:
4-cyano-4 -n-pentylbiphenyl, h-cyano-h -n-hexylbiphenyl, ^ -Cyano-U'-n-heptylbiphenyl, 4-cyano-4'-n-octylbiphenyl, 4-cyano- ^ ' -n-propoxybiphenyl, 4-cyano - ^ '- n-pentoxybiphenyl, 4-cyano - ^' - n-hexoxybiphenyl, 4-cyano-4'-n-heptoxybiphenyl, ^ -Cyano-4'-n-octoxybiphenyl and ^ -Cyano-V'-n-pentyl-pterphenyl and mixtures of these compositions.

Examples of other dichroic dyes used in a device according to the invention are:

No ₂ -ZoVn = N_ / o ~ \ - N (CH ₃ J ₂

= N - / ΟΛ - N (CH ₃ ) ₂ uVn m N- / oVn = N- / o) -N (CH ₃ ) ₂

\ l_ / 0 V-N = N— / o \ - N β N -_ / 0 \ -N = Ν— / θ \ —- N

\ l 0 N N / N N-_ N Ν / N

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Claims (2)

PlIN. 8li 1 7th 4th ι .77. PATENT CLAIMS : 1, image display device which contains a layer of a nematic liquid crystal with positive dielectric anisotropy (^ i J) t means for applying an electric field perpendicular to the layer and means with the help of which in the fieldless state a preferred orientation of the molecules of the liquid crystal parallel to the layer is brought about, characterized in that a dichroic dye is dissolved in the liquid crystal and the device is provided with means by means of which light transmitted by the liquid crystal layer is reflected with a polarization direction rotated by more than 90 °. 2. Image display device according to claim 1, which comprises a layer of a nematic liquid crystal with positive dielectric anisotropy ('I /' \ j) between a front plate and a rear plate, these plates having electrodes for applying an electric field in the layer perpendicular to the support plates are provided, and wherein the molecules of this liquid crystal in the fieldless state in both plates have a predetermined preferred orientation parallel to the layer in question, characterized in that a dichroic dye is dissolved in the liquid crystal and the device 70 9 837/0650 ORIGINAL INSPECTED PHN. 8317. ^ .1.77. a reflective layer on the side of the back plate and a Tf ^ retardation plate between the backplate and the reflective layer, the main optical directions of this -ς-Λ retardation plate at an angle of almost ^ 3 ° with the preferred orientation of the liquid crystal enclose on the back plate. 70 9 837/0650