DE3109309A1 - Process for the production of a liquid-crystal display - Google Patents

Abstract

It is proposed to produce the alignment layer of a liquid-crystal display from an organotin compound of the RnSnX4-n type (R = organic radical, X = reactive leaving groups, n = 1, 2 or 3). The organic radical is preferably an alkyl, and the reactive leaving group preferably comprises chlorine. The layer is expediently applied in a dip (immersion) process in which the compound is dissolved in an organic solvent, the solution is subsequently applied to the support plate, and the coating is then dried at moderately elevated temperatures. The resultant alignment layer is stable, adheres strongly to its substrate and gives the adjacent liquid-crystal molecules a defined tilt angle, whose size depends on the organotin compound and on the liquid-crystal substance and can be between 20 DEG and 90 DEG . Smaller tilt angles are obtained if the alignment layer is rubbed. The layers proposed are also particularly attractive since they can be rendered electroconductive - by doping and subsequent pyrolysis. Transparent electrodes and alignment layers can thus be produced in a very similar manner. <IMAGE>

Description

Method of manufacturing a liquid crystal display.

The invention relates to a method according to the preamble of claim 1. Such a manufacturing technique in which the orientation layer is generated from a silane with an alkyl radical and a hydrolyzable group, is known from DE-OS 22 38 429.

The silanization is one of the few orientation techniques that have advanced beyond the experimental stage and are of practical importance to have.

Because silane layers are relatively stable and adherent and deliver well-defined Liquid crystal textures and let.

especially compared to other common alignment methods such as inclined vapor deposition, relatively easy to manufacture. You just need dissolving the silane in water, applying the solution and then drying it. However, this manufacturing advantage is not too significant when you consider the Carrier plate coating considered as a whole: Usually there are four on the plate Layers, a protective layer, the conductive layer, an insulation layer and the orientation layer. Above all, the production of the conductive layer is labor-intensive and time-consuming, because the layer must first be produced in a CVD or in a sputtering process and then structure belts in an etching process.

Of course you could also without a separate orientation layer get by, namely if you give the liquid crystal layer certain surface-active Adds substances or acts on the conductive or protective layer in a certain way. Try in this direction however, as experience has shown has not led to satisfactory results.

The invention is therefore based on the object of adding another to the silanes To put aside a class of connections that just as easily make up layers of orientation can be produced with a similarly good alignment ability and, moreover, without any special Additional effort can be converted into transparent conductive layers. To the solution According to the invention, this object is achieved by a method having the features of patent claim 1 suggested.

Organotin compounds have already been synthesized in large numbers and researches (see, for example, "Chimica" 25 (1969) 313 or Gmelin Handbook of Inorganic Chemistry ", supplement to the 8th edition, volume 26, part I to VI, Springer-Verlag Berlin, Heidelberg, New York, 1975 to 1978). you will be has also been used technically for a long time, for example as stabilizers for Plastics, as catalysts for the polymerization of various monomers, as Bio and fungicides or as protective coatings. An application in the field of electro-optical Displays, however, had not yet been thought of.

The proposed compounds have an excellent one Adhesion that is at least equal to that of the silane layers. For this are the following processes on the substrate surface are responsible: The leaving groups are substituted by reaction with free SiOH or In-OH groups. Thereby split volatile compounds from, and Si-O-Sn resp.

In-O-Sn bridges that make the applied layer permanent on the substrate fix. As it turned out, the stratum itself is very permanent; allegedly Sn-O-Sn polymers are also formed.

The orientation effect of layers according to the invention depends greatly of the selected individual compound and the liquid crystal substance to be oriented away. For example, cyanobiphenyls are produced by alkyl-tin compounds with different Chain lengths are consistently homeotropically oriented, while phenylcyclohexanes only through Long-chain alkyl tin compounds are given a preferred direction perpendicular to the plate. Aromatic esters and mixtures of cyanobiphenyls and phenylpyrimidines behave are less extreme, they are with short or medium-length alkyl-tin compounds organic residues tilted planar and are tilted homeotropically adjusted, if the C chain in the organic residue has at least 7 members. The general rule is that Mono-n-alkyl-tin compounds even with shorter chain lengths perpendicular to the plate align as di-n-alkyl-tin compounds. This difference occurs with cyanobiphenyls practically nonexistent, shows up quite clearly with aromatic esters as well as mixtures of cyanobiphenyls and phenylpyrimidines and is with phenylcyclohexanes very pronounced.

The main cause for the observed orientation phenomena are certainly steric effects at the alignment layer / liquid crystal interface. Of the Layer go from more or less long organic groups, between which the adjacent liquid crystal molecules - either along their entire length or spatially suitable sections - be stored and anchored. Has the layer short-chain Groups, the cyano groups of the liquid crystal molecules usually shift in between, in the case of medium-length chains, it is preferably the alkyl or alkoxy groups of the liquid crystal molecules, and long C groups take the complete molecules on. Molecules with a sterically demanding structure, such as the phenylcyclohexyls with their "bulky" cyclohexyl group, only find extreme long Leftovers enough space. This explains the exceptional character of liquid kri stall systems based on phenylcyclohexanes. Also the different behavior of mono- and di-n-alkyl tin compounds becomes plausible if one considers steric phenomena based on: In the case of a di-n-alkyl compound, the angle between the two is organic residues, due to the tetrahedral structure at the central tin atom, about 1200. If the alkyl chains are short, they do not yet influence one another. The steric However, the influence increases with increasing chain length and can only be effective if the chain length is high Number of carbon atoms can be compensated by the greater mobility of the chains. Accordingly, only very short or very long molecular chains orient exactly homeotropically. In the case of mono-n-alkyl compounds, the tetrahedral structure on the tin atom causes the organic groups are practically perpendicular to the substrate surface. The groups also have a greater distance from one another, so that overall the steric Influence that reduces the angle of attack is less.

The angles of incidence of the liquid crystal molecules that are used in untreated Layers between 200 and 900 can be determined by thermal and / or mechanical Post-treatments of the orientation layer vary within relatively wide limits and if necessary also reduce to values below 200. For example, if you heat the layer to 2600, the angle of attack normally increases.

This tendency suggests that only at these temperatures the Reaction on the substrate surface is completely complete and the reactive Leaving groups that promote a planar orientation have completely disappeared. This assumption is also supported by the fact that an orientation layer heated to 260 ° the conductivity of the liquid crystal substance no longer increases, i.e. no ions more off can give. If you anneal at significantly higher temperatures, at around 520 ° C, a special planar orientation arises in which the texture of the layer support determines the direction of the liquid crystal director. Apparently loses the organotin compound under such a thermal load their organic residues and becomes a tin oxide without any orientation power of its own converted. The liquid crystal texture is hereafter. essentially through the Surface structure of the tin oxide base is determined.

Particularly small tilt angles, such as those for multiplexable ones Rotary cells are needed, come about when one tilts a planar orienting Layer rubs.

The proposed compounds are particularly attractive because because they not only have valuable orientation properties, but also can be easily converted into conductive layers. You only need to do this to mix the starting compound with a suitable additive, to apply the mixture and then oxidize through. In this way, guiding and orientation layers can be created produce that are very similar in their composition and also in their manufacture are; this makes the panel coating easier overall.

Further advantageous refinements and developments of the invention are the subject of additional claims.

The proposed solution should now be based on a liquid crystal display, which is shown in the attached figure in a somewhat schematic side section is to be explained in more detail.

The figure's liquid crystal display works with the so-called 'guest-host' effect. In detail, the cell contains a front support plate 1 and a rear support plate 2 and a reflector 3. The two carrier plates are sealed by a frame 4 connected to each other and wear on their opposing surfaces, respectively an electrically conductive coating (front electrode made of separately controllable segment electrodes 6, continuous back electrode 7) as well as a homeotropically orienting layer (orientation layers 8, 9). The chamber formed by the frame and the two substrates is covered with a liquid crystal layer 11 filled. This layer consists of a eutectic mixture of two azoxy compounds ("N4" from Merck), a chiral nematic substance and a pleochroic substance Dye are added. The layer is between an "off" homeotropic state and a planar cholesteric "on" state.

The orientation layer, which in the present case is an n-hexyl tin trichloride can be produced efficiently as follows: First, the organotin is dissolved Compound in an organic solvent such as toluene; the proportions be chosen so that a 0.2 to 5% solution is formed. Then you dive the carrier plate, which is otherwise already coated, takes a few minutes draws in the solution and then draws it in at a steady rate, such as 1 cm / sec., out again. If you wanted to be absolutely sure that there was no premature If hydrolysis takes place, the immersion process could be carried out in a suitable gas atmosphere, for example nitrogen. It is sufficient for this to be the immersion vessel with a to wash around laminar gas flow. After dipping, the substrate should be at 100 to 120 0C for 20 to 40 minutes.

The preparation of the starting compound for the alignment layer is either known from the literature or can easily be done in an analogous manner take place. In the following, therefore, only the synthesis of two representative groups of compounds, namely the alkyl tin chlorides and the alkyl tin alkoxides, are briefly outlined.

Alkvl-tin-chlorides First of all, tetraalkyl-tin compounds are produced using the so-called "Grignard reagent: R = n-C2H5, n-C3H7 to n-C12H25 and n-C16H33 This compound is then proportioned to alkyl-tin-chlorine compounds with various degrees of substitution: If the reaction time and the temperature are varied in this reaction, the reaction can be controlled - with constant stoichiometry - so that the desired products R2SnC12 and RSnC13 are formed in approximately equal parts as the main products in addition to very little R3SnCl. At low temperatures, after a short reaction time, a mixture of mono-, di- and trichloride is formed which, when heated, continues to react in a complex reaction process to form the final products.

Adding the above reaction equations gives the reaction equation for the observed formation of R2SnCl2 and RSnCl3 as the main products.

The variously substituted products can be removed by distillation separate.

Alkyl tin alkoxides Dialkyl tin diethoxides are produced by reacting dialkyl tin dichloride with sodium ethoxide in absolute ethanol at OOC.

To prepare the mono-alkyl-tin-triethoxides, the mono-alkyl-tin-trichlorides are reacted with sodium ethoxide in absolute ethanol at OOC.

Alkyl tin ethoxides with various degrees of substitution are synthesized via alkyl tin diethylamines.

Which of the many organotin compounds in the concrete The case to be selected depends mainly on which liquid crystal mixture is used is oriented and which angle of attack is to be produced. To one In the following, we will give an insight into the variety of possible orientation effects compiled, such as alkyl-tin-chlorides and alkyl-tin-alkoxides, the currently common ones Align liquid crystal substances.

Orientation in liquid crystal substances Connection ZLI 1132 ROTN 132 | ROTN 403 ROTN 570 (CH3) 2SnCl2 = = = 90 ° # (C2H5) 2SnCl2 = = 90 ° = 90 ° = 90 ° (C3H7) 2SnCl2 = = 90 ° = 90 ° # (C4H9) 2SnCl2 = # St = 90 ° # (C5H11) 2SnCl2 = = 900 = 900 (C6H13) 2SnCl2 = = <= 90 ° #> (C7H15) 2SnCl2 = = <= # (C8H17) 2SnCl2 = # # St # (C9H19) 2SnCl2 = # = # (C10H21) 2SnCl2 = # # # (C21H23) 2SnCl2 = # # # < (C12H25) 2SnCl2 # <# # # < (C16H33) 2SnCl2 # # # # CH3SnCl3 = = 90 ° = 90 ° # C2H5SnC13 = oV = 900 1 C3H7SnCl3 = = 90 ° = 90 ° # C4H9SnCl3 = 90 ° = 90 ° = 90 ° # C5H11SnCl3 = 900 = 900 = 900 1 < C6H13SnCl3 | = 90 ° | # | # | # C7R15SnCl3 1 tl # < C8H17SnCl3 # # <# # < C9H19SnCl3 # # <# # < Connection ZLI 1132 ROTN 132 ROTN 403 ROTN 570 C10H21SnCl3 # # <# # C11H23SnCl3 # # # # C12H25SnC13 1 1 1 1 C16H33SnC13 l 1 1 1 (C4Hg) 2Sn (OEt) 2 = 900 = = 900 - = 900 C4H9Sn (OEt) 3 = St 1 ll (C7H15) 2Sn (OEt) 2 = St l 1 1 In the table, =: planar orientation 1: homeotropic orientation:: tilted orientation oV: orientation without a clear preferred direction St: light-scattering orientation = 90 °: planar orientation in which the preferred direction above the conductive layer is perpendicular to the preferred direction above the uncoated substrate.

The liquid crystal mixtures measured are under the trade names mentioned available. The substance ZLI 1132 is a eutectic mixture of cyanophenylcyclohexanes from Merck, RO TN 132 is a eutectic mixture of biphenyl esters from Hoffmann-La Roche, who also developed the liquid crystal systems RO TN 403 (eutectic mixture of cyanobiphenylene and phenylpyrimidines) and RO TN 570 (eutectic mixture of Cyanobiphenylene). The liquid crystal cells on which the measurements were made were prepared as follows: The two carrier plates consisted of Glass and carried sputtered, 0.15 µm thick InO3-Sn02 conductive layers, which at 5200 tempered and with half-concentrated hydrochloric and nitric acid (mixing ratio 30: 1) had been structured. The Orient animal layers were applied in a dipping process and had a thickness between 0.02 and 0.1 / µm. Both plates were glued to one another at a distance of 12 μm.

The invention is limited. not on the detailed ones Embodiments. Organotin compounds are also used as orientation layers with reactive leaving groups other than chlorine and alcoholates and other organic ones Residues as alkylene in question.

Apart from that, the orientation layer could also be applied to others Wise to apply than in a dipping technique, for example by spraying, hurling or roll; A CVD process would also be conceivable. For the rest, the expert remains at liberty to in cases where a very specific tilt angle is important, also the base to give the orientation layer a defined profile.

1 Figure 11 claims

Claims (11)

Claims 1. A method for producing a liquid crystal display with two carrier plates which enclose a liquid crystal layer between them and an electrically conductive covering on each of their facing sides (Electrode) and over it carry an orientation layer, the orientation layer from an element organic compound of the type RnMX4 n (R = organic residue, M = tetravalent element, X = reactive leaving group and n = 1, 2 or 3) it becomes clear that the tetravalent element tin is. 2. The method according to claim 1, d a d u r c h g e -k e- n n z e i c h n e t that first the organotin compound in an organic solvent is solved that then the solution is applied to the carrier plate and then is heated. 3. The method according to claim 2, d a d u r c h g e -k e n n z e i c h n e t that the solution is applied by dipping the carrier plate and then heated at temperatures between 100 and 120 degrees for between 20 and 40 minutes will. 4. The method according to any one of claims 1 to 3, d a -d u r c h g e it is not stated that the organic radical is an alkyl, alkylamide, phenyl, Biphenyl, terphenyl, cyanophenyl, cyanobiphenyl, cyanoterphenyl, cyclohexyl, bicyclohexyl, Phenylcyclohexyl, biphenylcyclohexyl, cyanobiphenylcyclohexyl, phenylpyrimidine or Is cyanophenylpyrimidine. 5. The method according to any one of claims 1 to 4, d a- d u'r c h g e no indication that the reactive leaving group chlorine, Is bromine or iodine. 6. The method according to any one of claims 1 to 4, d a -d u r c h g e it is not noted that the reactive leaving group is an alcoholate of the type OR '(R' = alkyl or aryl) is. 7. The method according to any one of claims 1 to 6, d a -d u r c h g e it is not stated that the organotin compound is a mono-n-alkyl tin trichloride or a di-n-alkyl tin dichloride. 8. The method according to any one of claims 1 to 6, d a -d u r c h g e it is not stated that the organotin compound is a di-n-alkyl tin diethoxide or is a mono-n-alkyl tin triethoxide. 9. The method according to any one of claims 1 to 8, d a -d u r c h g e it is not noted that the electrode is prior to the creation of the orientation layer is formed in the following way: first, an organotin compound des of the same type with an oxide-capable additive, the oxide of which is the electrical Conductivity of tin oxide is increased, then the mixture on the carrier plate a layer is produced and finally the layer is heated in such a way that the organotin Compound and the additive are converted into their oxides. 10. The method according to claim 9, d a d u r c h g e -k e n n z e i c n e t that the addition of indium, antimony, cadmium or a rare earth of the formal Valence is +3 or +5. 11. The method according to claim 9 or 10, d a d u r c h g e k e n n z E i c h e t that the same organotin for the electrode and the orientation layer links be used.