JPH0534698A - Liquid crystal alignment film - Google Patents

Abstract

(57) [Summary] [Object] The present invention provides an alignment film for a low electric resistance liquid crystal, in particular, a liquid crystal element having excellent display characteristics. [Structure] An alignment film made of a conductive polymer containing a rubbed polypyrrole derivative polymer, or an ultrathin coating of a vertical alignment agent.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal device. In particular, it relates to an alignment film of liquid crystal molecules that affects the characteristics of a liquid crystal element.

[0002]

2. Description of the Related Art A liquid crystal device is obtained by filling a gap between both substrates with a liquid crystal composition. At this time, a commonly used alignment film is often composed of a simple substance of polyimide.

The concept of an alignment film of liquid crystal molecules is detailed in "Basics and Applications of Liquid Crystal Electronics" edited by Akio Sasaki.

[0004]

In a nematic liquid crystal element or a ferroelectric liquid crystal element, lowering the electric resistance of the alignment film can prevent adsorption of impurity ions,
It is desirable that the voltage threshold value of the voltage-transmittance characteristic of the device can be lowered, that the alignment is improved in the case of a ferroelectric liquid crystal device, and that a uniform liquid crystal device can be displayed. Further, in the alignment operation, so-called rubbing, there is a great advantage that the charge of the film can be reduced. However, the conventional polyimide-based alignment film has a high electric resistance of about 10 ¹⁵ Ωcm or more.
For this purpose, there is an attempt to mix the charge transfer complex into the polyimide-based alignment film, which means that the charge transfer complex is dissolved in the polyimide ink. That is, in order to realize this dissolution, the polyimide ink and the charge transfer complex have very large material restrictions or molecular structure restrictions, which is not practical.

Generally, the limit of pretilt angle at which liquid crystal molecules can be vertically arranged on a substrate with good uniformity is currently 10 °.
Weak (this is mainly the case for STNs, ie Super Twisted Nematics). Depending on the mode of the liquid crystal element, it is necessary to realize a much higher pretilt.

Particularly in a ferroelectric liquid crystal element, the influence of impurity ions in the liquid crystal is large. These seed ions are often adsorbed on the surface of the alignment film and have an adverse effect. Measures against this are desired.

[0007]

According to the present invention, in order to solve the above-mentioned problems, a liquid crystal alignment film provided in a liquid crystal element in which liquid crystal is sealed between opposing electrode substrates is aligned. It is intended to provide a liquid crystal alignment film composed of a polypyrrole derivative polymer film.

Further, according to the present invention, a liquid crystal alignment film provided in a liquid crystal device in which liquid crystal is sealed between opposing electrode substrates is formed by binding vertical alignment agent molecules on an aligned polypyrrole film. The liquid crystal alignment film is also made clear.

Further, according to the present invention, the liquid crystal alignment film provided in the liquid crystal device in which liquid crystal is sealed between the opposing electrode substrates is composed of a polypyrrole induction conductor and a polyimide resin, or a polypyrrole derivative and a polyparabanic acid resin, Also provided is a liquid crystal alignment film which is aligned.

According to the present invention, the liquid crystal alignment film provided in the liquid crystal element in which liquid crystal is sealed between the opposing electrode substrates is an alignment film composed of a polypyrrole derivative and a polyimide resin, or a polypyrrole derivative and a polyparabanic acid resin. There is also provided a liquid crystal alignment film obtained by binding molecules of a vertical alignment agent on the film.

[0011]

In general, by making the electric resistance of the alignment film semiconductive, it is possible to prevent the presence of localized charges due to the adsorption phenomenon of impurity ions, which often adversely affects the characteristics of the liquid crystal panel. This can improve the characteristics, particularly the alignment of the ferroelectric liquid crystals. It is immediately understandable that the threshold value can be lowered from the conventional value and that troubles due to static electricity during rubbing can be avoided.

As these conductive polymers, a polypyrrole derivative polymer film itself, a polymer composed of a polypyrrole derivative and a polyimide, or a polymer composed of a polypyrrole derivative and a polyparabanic acid resin is desirable.

As a secondary effect, particularly in the case of a ferroelectric liquid crystal device, an alignment film is formed by using a polypyrrole derivative and a polyimide resin or a polypyrrole derivative and a polyparabanic acid resin, and further performing an alignment treatment (usually a rubbing treatment). ), The mobile ions in the liquid crystal are extremely reduced. This is apparent in the triangular wave measurement. This effect is great when a minute amount of primary amine is mixed into the ferroelectric liquid crystal. This is very effective in preventing the image sticking and the abnormal alignment of liquid crystal molecules.

In the oriented or rubbed conductive polymer film, the pretilt angle of the liquid crystal molecules in contact with it is not so large. Therefore, it is desirable to increase the pretilt angle for the display using the homeo mode of the ferroelectric liquid crystal or the nematic liquid crystal.

Therefore, the molecules of the vertical alignment agent are adsorbed on the surface of the oriented conductive polymer film to further increase the pretilt angle. The injected liquid crystal molecules are arranged in the main chain direction of the oriented conductive polymer, but the pretilt angle at this time can be made larger. The adsorption of the molecules of the vertical alignment agent is performed by applying a vertical alignment agent diluted with a solvent such as alcohol with a spinner and heat-treating it. As the vertical aligning agent, ZLI-3334 or ZLI-3124 is used.
Etc. The pretilt angle can be largely changed depending on the concentration of dilution of the vertical alignment agent.

[0016]

EXAMPLES Examples of the present invention will be described below.

(Example 1)

[0018]

[Chemical 1]

A polypyrrole derivative polymer obtained by chemically oxidatively polymerizing the monomer represented by: was obtained from Nippon Soda. A 1.5 W% solution of this polymer in normal methyl 2 pyrrolidone (NMP) was prepared.

This solution was applied by a spinner onto a glass substrate having a patterned transparent conductive electrode on its main surface. The solvent NMP was heated and vaporized to obtain an organic film.

The film was rubbed with rayon fiber.
No electrostatic destruction of the film during rubbing occurred.

Using this substrate, a TN panel was manufactured by a known method. After that, a polarizing plate or the like was attached and the display characteristics were evaluated. In this panel, the voltage threshold of the voltage-transmittance characteristic was reduced by 20%, and the display was uniform.

Further, using this type of substrate, a ferroelectric liquid crystal element was manufactured by a known method. Uniform uniform orientation was obtained over the entire surface. The voltage threshold characteristic of the voltage-transmittance characteristic was also steep, and large-capacity matrix driving was possible.

(Example 2)

[0025]

[Chemical 2]

A polypyrrole derivative polymer obtained by chemically oxidatively polymerizing the monomer represented by: was obtained from Nippon Soda. A 1.5 W% solution of this polymer in normal methyl 2 pyrrolidone (NMP) was prepared.

This solution was applied by a spinner onto a glass substrate having a patterned transparent conductive electrode on the main surface. The solvent NMP was heated and vaporized to obtain an organic film.

The film was rubbed with rayon fiber.
No electrostatic destruction of the film during rubbing occurred.

The film was rubbed with rayon fiber.
No electrostatic destruction of the film during rubbing occurred.

A vertical aligning agent ZLI-3334 (ethanol solvent) manufactured by Merck & Co., which was diluted to 0.005 w%, was applied onto this with a spinner and heat-treated at about 120 ° C. for 30 minutes.

Using this substrate, an STN panel was manufactured by a known method. After that, a polarizing plate or the like was attached and the display characteristics were evaluated. In this panel, the voltage threshold value of the voltage-transmittance characteristic was lowered by about 10%, and the display was uniform.

According to another measurement, the pretilt angle of liquid crystal molecules in contact with this substrate was about 25 °.

Further, using this type of substrate, a ferroelectric liquid crystal element was manufactured by a known method. Uniform uniform orientation was obtained over the entire surface. The voltage threshold characteristic of the voltage-transmittance characteristic was also steep, and large-capacity matrix driving was possible. Also, the reliability was at a practical level.

(Example 3)

[0035]

[Chemical 3]

A polypyrrole derivative polymer obtained by chemically oxidatively polymerizing the monomer represented by: was obtained from Nippon Soda. A 0.2 W% solution of this polymer in normal methyl 2pyrrolidone (NMP) was prepared.

Normal Methyl 2 Pyrrolidone (NM
P) As a solvent, two types of ink having a resin content of 0.7 W% were prepared. Ink A is a polyamic acid resin PSI-A-2101 manufactured by Nitrogen Co., Ltd. and polyaniline of about 8: 2.
Ink B is manufactured by Tonen Petrochemical Co., Ltd., polyparabanic acid resin, sollac and polyaniline at about 9:
1 is included.

These were applied by a spinner onto a glass substrate having a patterned transparent conductive electrode on the main surface.

Next, in the case of ink A, 200 ° C. 18
In the case of ink B, heating was performed at 130 ° C. for 30 minutes.

The film was rubbed with rayon fiber.
No electrostatic destruction of the film during rubbing occurred.

Using a substrate corresponding to the ink A, a TN (twisted nematic) panel having a 90 ° twist was manufactured by a known method. After that, a polarizing plate or the like was attached and the display characteristics were evaluated. The display was more uniform than before. In this panel, the voltage threshold of the voltage-transmittance characteristic is about 10
%lowered.

Using this type of substrate corresponding to the ink B, a ferroelectric liquid crystal element was manufactured by a known method. Uniform uniform orientation was obtained over the entire surface. The voltage threshold characteristic of the voltage-transmittance characteristic was also steep, and large-capacity matrix driving was possible.

(Example 4)

[0044]

[Chemical 4]

A polypyrrole derivative polymer obtained by chemically oxidatively polymerizing the monomer represented by: was obtained from Nippon Soda. A 0.2 W% solution of this polymer in normal methyl 2pyrrolidone (NMP) was prepared.

Normal Methyl 2 Pyrrolidone (NM
P) As a solvent, two types of ink having a resin content of 0.7 W% were prepared. Ink A is a polyamic acid resin PSI-A-2101 manufactured by Nitrogen Co., Ltd. and polyaniline of about 8: 2.
Ink B is manufactured by Tonen Petrochemical Co., Ltd., polyparabanic acid resin, sollac and polyaniline at about 9:
1 is included.

These were applied on a glass substrate having a patterned transparent conductive electrode on the main surface by a spinner.

Next, in the case of ink A, 200 ° C. 18
In the case of ink B, heating was performed at 130 ° C. for 30 minutes.

The film was rubbed with rayon fiber.
No electrostatic destruction of the film during rubbing occurred.

A vertical aligning agent ZLI-3334 manufactured by Merck & Co., which was diluted to 0.005 w%, was coated on this with a spinner and heat-treated at about 120 ° C. for 30 minutes.

An STN panel was manufactured by a known method using a substrate corresponding to the ink A. After that, a polarizing plate or the like was attached and the display characteristics were evaluated. In this panel,
The voltage threshold of the voltage-transmittance characteristic was lowered by about 10%, and the display was uniform.

According to another measurement, the pretilt angle of liquid crystal molecules in contact with this substrate was about 25 °.

A ferroelectric liquid crystal element was manufactured by a known method using a substrate corresponding to the ink B. Uniform uniform orientation was obtained over the entire surface. The voltage threshold characteristic of the voltage-transmittance characteristic was also steep, and large-capacity matrix driving was possible. Also, the reliability was at a practical level.

[0054]

As described above, according to the present invention, it is possible to obtain an excellent liquid crystal element by appropriate treatment, and it is a great contribution to the industry.

Claims (4)

[Claims] 1. A liquid crystal alignment film, wherein a liquid crystal alignment film provided in a liquid crystal element in which liquid crystal is sealed between opposing electrode substrates comprises an oriented polypyrrole derivative polymer film. 2. A liquid crystal alignment film provided in a liquid crystal device in which liquid crystal is sealed between opposing electrode substrates, wherein a vertical alignment agent molecule is bonded onto an aligned polypyrrole film. Liquid crystal alignment film. 3. A liquid crystal alignment film provided on a liquid crystal element, in which liquid crystal is sealed between opposing electrode substrates, comprising a polypyrrole induction conductor and a polyimide resin, or a polypyrrole derivative and a polyparabanic acid resin, and being aligned. A liquid crystal alignment film, which is characterized in that 4. A liquid crystal alignment film provided in a liquid crystal device, in which a liquid crystal is sealed between opposing electrode substrates, wherein the liquid crystal alignment film comprises an oriented film composed of a polypyrrole derivative and a polyimide resin, or a polypyrrole derivative and a polyparabanic acid resin. A liquid crystal alignment film comprising a vertical alignment agent molecule bonded thereto.