CH653448A5 - DISPLAY DEVICE WITH HOST LIQUID CRYSTAL AND GUEST DYES. - Google Patents

Description

The present invention relates to a display device according to the preamble of claim 1.

It is known from US Pat. No. 4,032,219 to add dyes to guest-host liquid crystal displays in such a way that a black and white display is possible.

In the known display, the three colors red, blue and yellow are mixed with the liquid crystal. The blue, the dye Sudan Black (dark blue), has the maximum of the absorption curve at around 630 nm. The red, the color 5 substance Sudan IV, has the maximum of the absorption curve at around 520 nm. The yellow, the dye ß-carotenes , has the maximum of the absorption curve at around 500 nm.

The display shows light gray characters on a dark gray background. If no electrical voltage is applied to angelo, the color mixture produces a regular gray color.

The gray has a slight color. This is already hinted at in the patent specification itself, and is clearly recognizable in an analysis of the absorption spectrum of the display with the formula 15 for color differences according to CIE (1964).

The definition of the color difference according to CIE (1964) is known e.g. from N. Otha in Applied Optics (Sept. 1971, Vol. 10, No. 9, pp. 2183-2187).

The color difference was determined by subjective observations of several people. With a certain lighting, circles of the same color were determined in the color triangle UCS (CIE 1960). Details of this are known from the book "Color in Business and Industry" by Judd and Wyszecki.

25 A unit of color difference according to CIE (1964) is just barely distinguishable.

The only commercially available approximate black and white guest-host mix is known under the name RO-SA 605 from Hoffmann-La Roche, Basel. This mixture 30 consists of three dyes and has a fairly pronounced green-yellow color. An analysis of the spectrum clearly confirms this observation.

It is known that the absorption of an achromatic dye should be more or less constant in the visible region of the spectrum 35 (380-780 nm).

There are two ways to meet this achromasia condition:

Either the absorption spectra of the colors to be mixed can be adapted to the desired absorption spectrum 4o (spectral adaptation). This method requires the use of more than three dyes to achieve an acceptable match. Experience has shown that around 6 different dyes are required.

Or you can use the so-called metameric adaptation. For this purpose, the color and the luminance of the dye mixture and the desired color are coordinated. The absorption spectra of the dye mixture and the desired color are then not necessarily similar, in many cases even different. A calculation method using the matrix representation for three different colors under a particular lighting is described in the above-mentioned article by N. Otha. First, the definition of the color difference according to CIE (1964) and the trichromatic designation (X, Y, Z) are explained. Then the method of calculation is explained, which is actually based on Newton's method known from numerical mathematics. In particular, the color gamut is approximated by the mixture of the colors cyan, magenta and yellow at a color temperature of 4800 K.

The previous guest-host display devices, which have an approximately black-and-white display, all have a certain coloration with different lighting. This makes the display uncomfortable, even tiring for the human eye. The results of this An-65 pointing device are therefore unsatisfactory.

The invention is therefore based on the object of such a black and white display device with a host liquid crystal and only three different guest dyes

to design that the display appears achromatic in both artificial light and daylight.

According to the invention, this object is achieved by the features of claim 1.

The achromatic condition for two extreme illuminations, namely artificial and daylight, also ensures that the display appears achromatic with other illuminations. Extensive observations have clearly confirmed this fact.

The invention has the advantage, among other things, that a very high-contrast, achromatic image is produced with different illuminations. The display is still easy to read even from very small viewing angles.

The display device according to the invention in no way reveals the undesirable colorations that would otherwise occur in similar display devices.

Since there are no chromatographic effects, large-area guest-host display devices can now also be implemented with a black and white display.

An embodiment of the invention is explained below with reference to drawings. It shows:

1 shows a display device according to the invention, FIG. 2 shows the absorption spectra g, r and b of three dyes, and the absorption spectrum s of the mixture of the dyes with a nematic liquid crystal,

3 shows the emission spectra for artificial or daylight, FIG. 4 shows the absorption spectrum of the known guest-host mixture RO-SA 605,

Fig. 5 shows the absorption spectra g ', r' and b 'of three known dyes and the absorption spectrum s' of the mixture of

3,653,448

three dyes with a nematic liquid crystal.

1 shows a guest-host display device according to the invention. A liquid crystal 1, consisting of a mixture of the nematic liquid crystal E8 from Bri-5 table Drug House, England, and the three dyes G, R and B described in more detail below, is arranged between two plane-parallel plates 2 and 3. The plates 2 and 3 are hermetically sealed to form a cell by means of a sealing web 4. A 10 front electrode 6 and a back electrode 7 are arranged on the inner surfaces of the plates 2 and 3. The voltage source 8 is connected to the electrodes 6 and> 7 for changing the optical properties of the liquid crystal 1. A polarizer 5 is arranged on the end face of the plate 2.

15

The operation of such a display device is known from e.g. the article by G.H. Heilmeier et al. in Molecular Crystals and Liquid Crystals, 1969, Vol. 8, pp. 20 293-304, and is therefore not further explained.

The display device can also be provided with a cholesteric instead of a nematic liquid crystal. The polarizer 5 is then not present. Such a display device is known from e.g. D.L. White and 25 G.N. Taylor, Journal of Applied Physics, Vol. 45, No. November 11, 1974, pp. 4718-4723.

In the reflection mode, the plate 3 has a reflector (not shown) in a known manner.

The dyes G, R and B have the following chemical structural formulas:

G =

R =

B =

nc "" c 0 n = n - <f q nhc..h

Q OH

4 9

eOr

O

"O NHtO

sc2h4oc2h4sc2h4oh

? 2h5

n- (ch2) 3och2ch (ch2) 3ch3

In Figure 2, the absorption spectra g, r, b of the dyes G, R and B are shown. The absorption a is plotted on the ordinate and the wavelength X in nm on the abscissa.

The absorption spectrum s of the mixture of the dyes with the nematic liquid crystal E8 is measured at a layer thickness of 10 μm with light polarized parallel to the optical axis. The optical axis is the direction in which the molecules of the host nematic liquid crystal are oriented. The main absorption direction of the dye molecules also corresponds to this.

The focal wavelengths of the absorption spectra g, r and b are 451.0 nm, 531.7 nm and 644.8 nm, the focal wavelength Xo of an absorption curve I (A.) being defined by:

q0 ^ l (X) dX

If the dyes G, R and B are mixed with 0.503.1.557 and 2.369 percent by weight with the nematic liquid crystal E8, the color differences up to the achromatic point for daylight or artificial light are 0.0 or 0.4

Units. If these percentages by weight are 0.499, 1.550 or 2.371, these color differences are 0.4 or 0.0.

As already mentioned, a unit of the color difference can be precisely distinguished, so that the above mixture certainly appears achromatic, because the differences are clearly much smaller than 1.

FIG. 3 shows the emission spectra T and K for daylight (CIE source D65) and for artificial light (CIE standard 55 source A), with which the absorption spectra shown in FIG. 2 are measured. The intensity i is plotted on the vertical axis in arbitrary units. The wavelength X is plotted in nm on the horizontal axis. The spectrum for artificial light shows a greater intensity with increasing wavelength, the spectrum for daylight shows an increasing, then a weakly decreasing intensity at longer wavelengths.

FIG. 4 shows the absorption spectrum of the guest-host mixture RO-SA 605. The absorption a is plotted again in the vertical direction and the wavelength X in the horizontal direction. The curve was measured with light polarized parallel to the optical axis. The Dik-

653 448 4

ke of the liquid crystal layer is selected so that the transmittance of this known guest-host mixture is evidently 5%. The absorption maxima are not achromatic.

at about 382,485,590 and 636 nm. The color difference up to in Fig. 5 are the absorption spectra g ', r', b 'of the

The achromatic point in artificial light (CIE standard source dyes G ', R' and B 'recorded. The chemical le A) is 13.3 units. In daylight (CIE source D65) 5 structural formulas of these dyes are listed below: this difference is 14.4 units.

G'

R '

B '

oh ö nh2

The focal wavelengths of the absorption curves 20, a black and white achromatic display, principally possible-g ', r' and b ', are 433.9 nm, 486.8 nm and 599.3 nm, respectively. In addition, the concentrations should also be correct

The absorption spectrum s' of the mixture of these colors can be chosen.

substances with the nematic liquid crystal E8 is again measured. The display device according to the invention can measure both a layer thickness of 10 Jim with parallel to the optical axis bright characters on a dark background, and vice versa polarized light. Have 25 dark characters on a light background. With

If the dyes G ', R' and B 'with 0.36, 0.37 and 1.51, respectively, with the help of so-called dot matrix displays, weight percentages with the nematic liquid crystal E8 can also be used to display graphics, because mixed is for Daylight the color difference is zero, the invention is particularly suitable for large-area display - but is 9.3 units for artificial light. devices. If the grid of such dot matrix displays

At other concentrations of the dyes G ', R' and B ', 30 gen is chosen sufficiently small and internal spacers namely 0.45.0.26 or 1.67 percent by weight, which is arranged in the cell, can also be screens for color difference for artificial light it is zero, for daylight television sets and the like it is especially well made 8.5 units. will.

As you can see, this dye mixture is not achromatic for both types of lighting. 35 The invention is not restricted to guest-host displays.

Even with other concentrations of the dyes, there is no device with a positive dichroism, but also an achromatic display with the two illuminations, devices with a negative dichroism have an achromatic display. black and white display when the center of gravity wavelength

It is only when the focus wavelengths of the absorption of the absorption spectra of the three dyes in the invention spectra are in the areas according to the invention that there are 40 areas according to the invention.

h3co- <j7> n = n - <ïï ^ -n = n - <ö> n = n- <ö> -och3

ch, -3

nc - <^ vn = n- ^ y> -n = ch "<rô ^> - n (ch ..)

3 2

nh- 0

sc2h40c2h4sc2k40h c

3 sheets of drawings

Claims (8)

653448 PATENT CLAIMS 1. Display device with liquid crystal (1) consisting of: - from two plane-parallel plates (2, 3), which together with a locking web (4) form a cell, - from two electrode layers (6,7) on the inner surfaces of the plates (3,4), - From a host liquid crystal, and - from three different pleochroic guest dyes G, R, B, which are mixed with the host liquid crystal, characterized in that: - The focus wavelengths of the absorption spectra of the three dyes G, R, B are in the following ranges: 450 ± 15.545 ± 15 or 650 ± 15 nm. 2. Display device according to claim 1, characterized in that the host liquid crystal is nematic, and a polarizer (5) is provided on the front plate (2). 3. Display device according to claim 1, characterized in that the host liquid crystal is cholesterol. 4. Display device according to claim 2 or 3, characterized in that the display has a color difference measured according to CIE (1964) up to the achromatic point less than 0.9 units for both artificial and daylight. 5. Display device according to claim 1, characterized in that the guest dyes G, R, B in the host liquid crystal each have the following concentrations in percent by weight: 0.5 ± 0.5, 1.5 ± 0.5 and 2.5 ± 0.5 6. Display device according to claim 5, characterized in that the yellow dye G has the following chemical structural formula: nc- <"0> n = n <0 7. Display device according to claim 5, characterized in that the red dye R has the following chemical structural formula: O OH sc2h4oc2h4sc2h4oh O NH * 8. Display device according to claim 5, characterized in that the blue dye B has the following chemical structural formula: O NW * q ? 2H5 n- (ch2) 3och2ch (ch2) 3ch