KR20080014094A - Liquid crystal composition, liquid crystal display element using the same, and electronic paper comprising said liquid crystal display element - Google Patents

Abstract

[PROBLEMS] To provide a liquid crystal composition, which can satisfactorily reduce light scattering in a focal conic state, and a liquid crystal display element having an improved color balance and an improved contrast and an electronic paper using the same. [MEANS FOR SOLVING PROBLEMS] The content of a chiral material in a cholesteric liquid crystal LCg for G is rendered higher than the content of the chiral material in a cholesteric liquid crystal LCb for B. The content of a chiral material in a cholesteric liquid crystal LCr for R is rendered higher than the content of the chiral material in a cholesteric liquid crystal LCg for G. The chiral material in the cholesteric liquid crystal LCr for R comprises about 5% by weight of a chiral material CHl1 as an L material mixed into a base liquid crystal as an R material. The base liquid crystal comprises a nematic liquid crystal LCn and 27% by weight of a liquid crystalline chiral material CHr1 as an R material and 3% by weight of a noncrystalline chiral material CHr2 as an R material incorporated into the nematic liquid crystal LCn.

Description

Liquid crystal composition and liquid crystal display element using the same, and electronic paper provided with the same TECHNICAL FIELD

This invention relates to the liquid crystal composition in which a cholesteric phase is formed, the liquid crystal display element using the same, and the electronic paper provided with the same.

In recent years, the development of electronic paper is actively progressed in each company, each university, and the like. BACKGROUND ART As an application market in which electronic paper is expected, various application portable devices such as subdisplays of mobile terminal devices and display units of IC cards, such as electronic books, have been proposed. One of the strong display methods of electronic paper is a display element using a liquid crystal composition (cholesteric liquid crystal) in which a cholesteric phase is formed. The cholesteric liquid crystal has excellent characteristics such as semipermanent display holding characteristics (memory characteristics), vivid color display characteristics, high contrast characteristics and high resolution characteristics.

FIG. 10 schematically shows the cross-sectional structure of a liquid crystal display element 51 capable of full color display using a cholesteric liquid crystal. The liquid crystal display element 51 has the structure which the blue (B) display part 46b, the green (G) display part 46g, and the red (R) display part 46r were laminated | stacked in order from the display surface. In the illustration, the upper substrate 47b side is the display surface, and external light (solid arrow) enters the display surface from the upper side of the substrate 47b. Moreover, the eye of an observer and its observation direction (dotted arrow) are typically shown on the board | substrate 47b upper side.

The B display portion 46b is a pulse for applying a predetermined pulse voltage to the liquid crystal layer 43b for blue (B) and the liquid crystal layer 43b for B sealed between the pair of upper and lower substrates 47b and 49b. It has a voltage source 41b. The G display portion 46g is a pulse for applying a predetermined pulse voltage to the green (G) liquid crystal layer 43g and the G liquid crystal layer 43g sealed between the pair of upper and lower substrates 47g and 49g. It has a voltage source 41g. The R display portion 46r is a pulse for applying a predetermined pulse voltage to the red (R) liquid crystal layer 43r and the R liquid crystal layer 43r sealed between the pair of upper and lower substrates 47r and 49r. It has a voltage source 41r. The light absorption layer 45 is arrange | positioned at the back surface of the board | substrate 49r under the R display part 46r.

The cholesteric liquid crystals used in the liquid crystal layers 43b, 43g, and 43r for each of B, G, and R have relatively large amounts of chiral additives (also called chiral materials) in nematic liquid crystals at a content of several ten percent by weight. It is an added liquid crystal mixture. When a relatively large amount of chiral material is contained in the nematic liquid crystal, the nematic liquid crystal molecular layer can form a strongly helical bitten cholesteric phase. Cholesteric liquid crystals are also called chiral nematic liquid crystals.

The cholesteric liquid crystal is bistable (memory) and can take either of the planar state or the focal conic state by adjusting the electric field strength applied to the liquid crystal, and once the planar state or the focal conic state After the state, the state is stably maintained even under the electromagnetic field. The planar state can be obtained by applying a predetermined high voltage between the upper and lower substrates 47 and 49 to provide a strong electric field to the liquid crystal layer 43, and then rapidly bringing the electric field to zero. The focal conic state can be obtained, for example, by applying a predetermined voltage lower than the high voltage between the upper and lower substrates 47 and 49 to provide the electric field to the liquid crystal layer 43, and then rapidly bringing the electric field to zero.

The display principle of the liquid crystal display element using the cholesteric liquid crystal will be described taking the B display portion 46b as an example. 11A shows the alignment state of the liquid crystal molecules 33 of the cholesteric liquid crystal in the planar state of the B liquid crystal layer 43b of the B display portion 46b. As shown in Fig. 11A, the liquid crystal molecules 33 in the planar state are sequentially rotated in the substrate thickness direction to form a spiral structure, and the spiral axis of the spiral structure is substantially perpendicular to the substrate surface.

In the planar state, light of a predetermined wavelength depending on the spiral pitch of the liquid crystal molecules is selectively reflected by the liquid crystal layer. If the average refractive index of the liquid crystal layer is n and the spiral pitch is p, the wavelength λ at which reflection is maximum is represented by λ = n · p.

Therefore, in order to selectively reflect blue light in the planar state in the B liquid crystal layer 43b of the B display part 46b, the average refractive index n and the spiral pitch p are determined so that (lambda) = 480 nm, for example. . Average refractive index n can be adjusted by selecting a liquid crystal material and a chiral material, and spiral pitch p can be adjusted by adjusting the content rate of a chiral material.

FIG. 11B shows the alignment state of the liquid crystal molecules 33 of the cholesteric liquid crystal in the B liquid crystal layer 43b of the B display portion 46b in the focal conic state. As shown in FIG. 11B, the liquid crystal molecules 33 in the focal conic state are sequentially rotated in the in-plane direction of the substrate to form a spiral structure, and the spiral axis of the spiral structure is substantially parallel to the substrate surface. In the focal conic state, the selectivity of the reflection wavelength is lost in the B liquid crystal layer 43b, and most of the incident light is transmitted. The transmitted light is absorbed by the light absorbing layer 45 disposed on the rear surface of the substrate 49r below the R display portion 46r, so that dark (black) display can be realized.

As described above, in the cholesteric liquid crystal, the reflection transmission of light can be controlled in the alignment state of the liquid crystal molecules 33 twisted in a spiral form. The cholesteric liquid crystal which selectively reflects green or red light at the time of planar state to G liquid crystal layer 43g and R liquid crystal layer 43r similarly to said B liquid crystal layer 43b, respectively. The liquid crystal display element 51 of full color display is manufactured by sealing.

12 shows an example of the reflection spectrum in the planar state of each of the liquid crystal layers 43b, 43g, and 43r. The horizontal axis represents the wavelength of reflected light (nm), and the vertical axis represents the reflectance (white plate ratio;%). The reflection spectrum in B liquid crystal layer 43b is shown by the curve which connects a mark in the figure. Similarly, the reflection spectrum in the G liquid crystal layer 43g is indicated by a curve connecting the display, and the reflection spectrum in the R liquid crystal layer 43r is indicated by the curve connecting the ◆ display.

As shown in FIG. 12, since the center wavelength of the reflection spectrum in the planar state of each liquid crystal layer 43b, 43g, 43r becomes long in order of B, G, and R, a cholesteric liquid crystal Spiral pitch of is lengthened in order of liquid crystal layer 43b, 43g, 43r. Therefore, the content rate of the chiral material of the cholesteric liquid crystals of the liquid crystal layers 43b, 43g and 43r needs to be lowered in the order of the liquid crystal layers 43b, 43g and 43r.

In general, the shorter the reflection wavelength, the stronger the twist of the liquid crystal molecules and the shorter the pitch. Therefore, the content of the chiral material in the cholesteric liquid crystal is increased. Moreover, in general, the higher the content of the chiral material, the higher the driving voltage tends to be. Further, the reflection band width Δλ increases as the refractive index anisotropy Δn of the cholesteric liquid crystal increases.

Patent Document 1: Japanese Patent Laid-Open No. 2003-147363

Patent Document 2: Japanese Patent Application Laid-Open No. 2004-2765

<Start of invention>

Problems to be Solved by the Invention

By the way, the color liquid crystal display element of the laminated structure of R, G, and B using a cholesteric liquid crystal has a subject that the balance deterioration of a color reproduction range and a fall of contrast are easy to produce. The balance of the color reproduction range and the good or bad of the contrast largely depend on the scattering of light in the dark state, that is, the layer in the focal conic state. For example, when the liquid crystal layer of any one color is in a planar state, and the remaining two color liquid crystal layers are in the focal conic state, when the scattering of light in the liquid crystal layer in the focal conic state is large, the liquid crystal layer in the planar state The scattered portion of the light in the liquid crystal layer in the focal conic state is applied to the reflected light as noise. As a result, the color purity of the display color is lowered. In addition, in the case of black display, all the liquid crystal layers of RGB are in a focal conic state, but when light scattering in each liquid crystal layer is large, black density falls remarkably. That is, the contrast of the display image is reduced, resulting in faint display.

The physical property governing light scattering of the liquid crystal layer in the focal conic state is considered to be the refractive index anisotropy Δn inherent in the liquid crystal material. Fig. 13 shows the relationship between the refractive index anisotropy Δn and the reflection of light in the liquid crystal layer. Fig. 13A shows the relationship between the refractive index anisotropy Δn in the planar state and the brightness of the reflected light. The horizontal axis represents refractive index anisotropy Δn, and the vertical axis represents brightness (white plate ratio;%). Fig. 13B shows the relationship between the refractive index anisotropy Δn and the scattering of light in the focal conic state. The horizontal axis represents refractive index anisotropy Δn, and the vertical axis represents scattering (white plate ratio;%).

As shown in Figs. 13A and 13B, since increasing the Δn value increases the reflectance of the liquid crystal layer in the planar state, the display screen brightness of the liquid crystal display element is improved, but the light scattering degree of the liquid crystal layer in the focal conic state is increased. Rises at the same time. On the other hand, when the value of Δn is decreased, light scattering of the liquid crystal layer in the focal conic state is reduced, but the reflectance of the liquid crystal layer in the planar state is also lowered, so that the brightness of the display screen is lowered. In this way, the brightness and scattering of the reflected light are in a trade-off relationship, and both of the good brightness and low scattering of the display screen are difficult only by controlling the? N value.

Patent Document 1 discloses that the cholesteric liquid crystal of each liquid crystal layer for RGB differs in the mixing ratio between the R and S bodies, which are two optical isomers in which the chiral material's optical selectivity is different, and the amount of chiral material added is the same in each liquid crystal layer. The technique for making it is disclosed. However, even if the amount of chiral material added to each liquid crystal layer for RGB is the same and the physical properties such as Δn are the same, the light scattering characteristics are different for each liquid crystal layer, so that it is difficult to completely improve the color balance and contrast of the display screen. Do.

An object of the present invention is to provide a liquid crystal composition capable of sufficiently reducing scattering of light in a dark state (focal conic state).

Moreover, the objective of this invention is providing the liquid crystal display element excellent in the improvement of the color balance and the improvement of contrast, and the electronic paper using the same.

Means for Solving the Invention

The object is a first liquid crystal layer comprising a first chiral material contained in a nematic liquid crystal so as to reflect light of a first wavelength in a planar state to form a cholesteric phase, and said first in a planar state Having a second liquid crystal layer having a second chiral material contained in the nematic liquid crystal at a content higher than the content of the first chiral material so as to reflect light of a second wavelength longer than the wavelength to form a cholesteric phase. It is achieved by the liquid crystal display element characterized by the above-mentioned.

In the liquid crystal display device of the present invention, the second chiral material includes two kinds of optical isomers having different optical selectivities.

Moreover, the said objective is achieved by the electronic paper characterized by the electronic paper which has a display part which displays a predetermined image, The said display part is equipped with the liquid crystal display element of the said invention.

Moreover, the said objective is a liquid crystal composition provided with the nematic liquid crystal and the chiral material contained in this nematic liquid crystal and forming a cholesteric phase, The said chiral material is the light of the 2nd wavelength longer than a 1st wavelength in a planar state. It is achieved by the liquid crystal composition characterized by having a content rate higher than the content rate which reflects the light of a said 1st wavelength so that it may reflect.

Moreover, the said objective is achieved by the liquid crystal composition characterized by having a nematic liquid crystal and a chiral material added in the said nematic liquid crystal in order to form a cholesteric phase with refractive index anisotropy smaller than this nematic liquid crystal. .

Effect of the Invention

According to the present invention, a liquid crystal composition capable of sufficiently reducing scattering of light in a dark state can be realized.

Moreover, according to this invention, the liquid crystal display element excellent in color balance and contrast, and the electronic paper using the same can be implement | achieved.

Best Mode for Carrying Out the Invention

The liquid crystal composition according to one embodiment of the present invention, a liquid crystal display element using the same, and an electronic paper provided with the same will be described with reference to FIGS. 1 to 9. First, the basic principle of reducing light scattering in the dark state and the liquid crystal composition using the same will be described with reference to FIGS. 1 to 3. The inventors found that scattering of light in a focal conic state generally involves a liquid crystal layer for blue (B) reflecting blue light in a planar state, a liquid crystal layer for green (G) reflecting green light, and a liquid crystal for red (R) reflecting red light. It became strong in order of layers, and since the light scattering in the liquid crystal layer for R is especially strong, it discovered that blue or green color purity was greatly reduced, and earnestly examined about the improvement.

First, the reason why the scattering of light in the R liquid crystal layer becomes relatively strong will be described with reference to FIG. 1. 1A, 1B, and 1C are focal conic states of liquid crystal layers 43b, 43g, 43r of B, G, and R of the conventional color liquid crystal display element 51 shown in FIGS. 10 and 11, respectively. The orientation state of the liquid crystal molecule 33 of the cholesteric liquid crystal in is shown. FIG. 1A shows the B liquid crystal layer 43b, FIG. 1B shows the G liquid crystal layer 43g, and FIG. 1C shows the R liquid crystal layer 43r.

The content ratio (= 100 × (weight of chiral material contained) / (weight of cholesteric liquid crystal)) of the chiral material of the cholesteric liquid crystal (mixture of nematic liquid crystal and chiral material) of the conventional liquid crystal layer for B (b) is It is 30 weight% (wt)%, the content rate of the chiral material of G liquid crystal layer 43g is 27 weight%, and the content rate of R liquid crystal layer 43r is 23 weight%.

1A, 1B, and 1C, the liquid crystal molecules 33s near the substrate surface of the upper and lower substrates 47b and 49b sequentially rotate in the in-plane direction to form a spiral structure, and the spiral axis of the spiral structure is a substrate. The focal conic is almost parallel to the face. This is considered to be because the orientation control force from the substrate strongly acts on the liquid crystal molecules at the interface between the substrate and the liquid crystal.

On the other hand, the orientation regulating force of the substrate surface does not directly act on the liquid crystal molecules 33b in the center portion (bulk region) in the cell thickness direction, and orientation propagation due to the continuity of the liquid crystal becomes dominant. At this time, when the content rate of the chiral material is relatively high, the orientation regulation force can be propagated to the bulk region, but when the content rate is low, sufficient orientation force cannot be propagated to the bulk region.

Therefore, in the B liquid crystal layer 43b having a high content of chiral materials, a sufficient focal conic state appears almost uniformly in the cell thickness direction, but the G liquid crystal layer 43g having a relatively low content of chiral materials and the liquid crystal layer for R are present. At 43r, an orientation state different from the focal conic state may occur in the bulk region. Although the nonuniformity of the spiral-axis direction of the liquid crystal of a bulk area | region becomes large in G liquid crystal layer 43g, it is thought that the nonuniformity of the spiral structure containing a spiral pitch as well as the direction of a spiral axis in R liquid crystal layer 43r becomes large. . Thus, as the content rate of the chiral material is lowered, it is considered that the orientation defect of the bulk region in the focal conic state increases, and thus the degree of scattering of light increases.

The above is the reason which can be considered that the scattering of the light in R liquid crystal layer becomes relatively strong.

On the other hand, the said cause suggests that the chiral material contained in a nematic liquid crystal and forming a cholesteric phase has the suppressive effect of the spiral structure nonuniformity of a liquid crystal molecule.

Therefore, in this embodiment, the content rate of the chiral material of the liquid crystal composition which reflects the light of the 2nd wavelength longer than a 1st wavelength in a planar state is more than the content rate of the chiral material of the liquid crystal composition which reflects light of the 1st wavelength in a planar state At the same time, the chiral material was based on the principle of containing two kinds of optical isomers having different optical properties. In addition, in this paper, although these optical isomers are respectively called and demonstrated as R body and L body, these are the same meaning as R body and S body by the R / S notation method.

The liquid crystal composition (cholesteric liquid crystal) using the said basic principle which reduces the scattering of light in a dark state is manufactured as a base composition with the base (reference) liquid crystal of L body which is an R body or its optical isomer.

The base liquid crystal of R body is manufactured by adding predetermined weight the chiral material CHr1 of R body and the chiral material CHr2 of R body to nematic liquid crystal LCn of predetermined weight. The content rate of chiral material CHr1 (weight ratio (weight%) with respect to the total weight of nematic liquid crystal LCn, and 2 types of chiral materials CHr1 and CHr2; same thing below) is 27 weight%. The content rate of chiral material CHr2 is 3 weight%. Hereinafter, chiral material CHr1 and chiral material CHr2 contained are collectively called chiral material CHr.

Nematic liquid crystal LCn is refractive index anisotropy (DELTA) n = 0.25, dielectric anisotropy (DELTA) epsilon (= epsilon) = 20, and the viscosity (micrometer) = 50 (mPa * s) at room temperature, for example. Chiral material CHr1 has (DELTA) n = 0.22, (DELTA) (epsilon) = 22, for example, and the force HTP = 10 of winding a helix. As for chiral material CHr2, (DELTA) n value and (DELTA) epsilon value are the same as chiral material CHr1, and HTP = 20. The dominant wavelength lambda b of the selective reflection of the base liquid crystal of the produced R body is about 480 nm, and Δn = 0.23.

For example, the physical property value of nematic liquid crystal LCn is measured or calculated as follows. First, nematic liquid crystal LCn is inject | poured into the glass test cell. Subsequently, the specific resistance, dielectric constant, etc. of the nematic liquid crystal LCn are measured and calculated using a commercially available LCR meter. In addition, a viscosity is measured with a commercially available viscometer.

Further, Δn of the nematic liquid crystal LCn is measured by a commercially available Abbe refractometer or the like. In addition, the capacitance of each of the test cells into which the liquid crystals in which the horizontal alignment and the vertical alignment are injected is respectively measured, and Δε of the nematic liquid crystal LCn is calculated. Δε is the difference between the dielectric constant in the direction of the director (average direction of the long axis of the liquid crystal molecules) and the dielectric constant of the component perpendicular thereto.

The L-shaped base liquid crystal is produced by adding a predetermined weight to an L-shaped chiral material CHl1 and an L-form chiral material CHl2 to a predetermined weight of nematic liquid crystal LCn. The content rate of chiral material CHl1 (weight ratio (weight%) with respect to the total weight of nematic liquid crystal LCn, and two types of chiral materials CHl1 and CHl2; the same below) is 27 weight%. The content rate of chiral material CHl2 is 3 weight%. Hereinafter, the chiral material CHl1 and the chiral material CHl2 contained are collectively called chiral material CHl.

(DELTA) n value, (DELTA) epsilon value, and viscosity (micro) of the nematic liquid crystal LCn of the base liquid crystal of L body are the same as that of the base liquid crystal of the said R body. The Δn value, the Δε value, and the HTP value of the chiral material CHl1 are the same as those of the chiral material CHr1 of the R body. The Δn value, the Δε value, and the HTP value of the chiral material CHl2 are the same as those of the chiral material CHr2 of the R body. In addition, (lambda) b and (DELTA) n of the produced base L liquid crystal are the same as that of the base liquid crystal of said R body. In addition, the nematic liquid crystal LCn and the chiral materials CHr1, CHr2, CH1, and CHl2 use ordinary commercially available materials.

2 shows the material composition ratio of the liquid crystal composition in which the base liquid crystal of the R or L body is used for the basic composition. FIG. 2A shows the composition ratio of the cholesteric liquid crystal used for the B liquid crystal layer (first liquid crystal layer) reflecting blue light (light of the first wavelength) in the planar state, and FIG. The composition ratio of the cholesteric liquid crystal used for the G liquid crystal layer (second liquid crystal layer) reflecting light (light of the second wavelength) is shown, and FIG. 2C reflects red light (light of the third wavelength). The composition ratio of the cholesteric liquid crystal used for the R liquid crystal layer (third liquid crystal layer) to be shown.

As shown in FIG. 2A, the base liquid crystal of R body (henceforth B cholesteric liquid crystal LCb) is used for B liquid crystal layer. That is, the dominant wavelength? B of the selective reflection of the cholesteric liquid crystal LCb for B is about 480 nm, and Δn = 0.23.

As shown in Fig. 2B, a liquid crystal (hereinafter, referred to as cholesteric liquid crystal LCg for G) is used as the liquid crystal layer for G, in which the base liquid of the L body is mixed with the chiral material CHr1 of the R body at a content of about 3% by weight. . The dominant wavelength? G of the selective reflection of the G cholesteric liquid crystal LCg is about 560 nm, and the Δn value is almost the same as that of the B cholesteric liquid crystal.

As shown in Fig. 2C, a liquid crystal (hereinafter referred to as cholesteric liquid crystal LCr for R) is used in which the liquid crystal layer for R is mixed with the base liquid of the R body at a content of about 5% by weight of the chiral material CHl1 of the L body. . The dominant wavelength? R of the selective reflection of the R-cholesteric liquid crystal LCr is about 610 nm, and the Δn value is almost the same as that of the B-cholesteric liquid crystal.

As described above, in the present embodiment, the optical sensitivities (R) of the cholesteric liquid crystals LCb and LCr for B and R are the same, and are different from the optical sensitivities (L) in the cholesteric liquid crystal LCg for G. In addition, the content ratio of the chiral material is higher for the G cholesteric liquid crystal LCg than for the B cholesteric liquid crystal LCb, and for the R cholesteric liquid crystal LCr than the G cholesteric liquid crystal LCg. In addition, cholesteric liquid crystal LCb, LCg, LCr for B, G, and R forms a cholesteric phase at room temperature.

Next, the liquid crystal display element and electronic paper which used said cholesteric liquid crystal LCb, LCg, LCr for B, G, and R are demonstrated using FIGS. 3 shows a schematic configuration of a liquid crystal display element 1 according to the present embodiment. 4 schematically shows the cross-sectional structure of the liquid crystal display element 1.

3 and 4, the liquid crystal display element 1 includes a liquid crystal layer B (first liquid crystal layer) 3b for reflecting blue light (light of a first wavelength) in a planar state. G display part 6g provided with one B display part 6b, and the liquid crystal layer for G (2nd liquid crystal layer) 3g which reflects green light (light of a 2nd wavelength) in a planar state, It has R display part 6r provided with R liquid crystal layer (third liquid crystal layer) 3r which reflects red light (light of a 3rd wavelength) in a negative state. Each display part 6b, 6g, 6r of B, G, and R is laminated | stacked from the light-incidence surface (display surface) side in this order.

The B display part 6b has a pair of opposing upper and lower substrates 7b and 9b and a B liquid crystal layer 3b sealed between the two substrates 7b and 9b. The liquid crystal layer 3b for B has the cholesteric liquid crystal LCb for B of the composition shown to FIG. 2A.

The G display part 6g has a pair of opposing upper and lower substrates 7g and 9g and a liquid crystal layer 3G for G sealed between the two substrates 7g and 9g. G liquid crystal layer 3g has G cholesteric liquid crystal LCg of the composition shown to FIG. 2B.

The R display portion 6r includes a pair of upper and lower substrates 7r and 9r arranged oppositely, and a liquid crystal layer 3r for R sealed between the two substrates 7r and 9r. The liquid crystal layer 3r for R has the cholesteric liquid crystal LCr for R of the composition shown to FIG. 2C.

In the laminated structure of each display part 6b, 6g, and 6r of B, G, and R, the opticality in the liquid crystal layer 3g for G in a planar state, and the liquid crystal layer for B and R ( 3b) and (3r), the light of the right circularly polarized light in the liquid crystal layer 3b in B is overlapped in the region where the blue and green and green and red reflection spectra shown in FIG. 12 overlap. The light of the left circularly polarized light can be reflected by the G liquid crystal layer 3g. Accordingly, the loss of the reflected light can be reduced to improve the brightness of the display screen of the liquid crystal display element 1.

The upper substrates 7b, 7g, 7r, and the lower substrates 9b, 9g, 9r need to have light transparency. In this embodiment, two polycarbonate (PC) film board | substrates cut | disconnected in the magnitude | size of 10 cm x 8 cm were used. In addition, a film substrate such as a glass substrate or polyethylene terephthalate (PET) may be used instead of the PC substrate. In the present embodiment, the upper substrates 7b, 7g, 7r, and the lower substrates 9b, 9g, 9r are all light-transmitting, but the lower substrates of the R display portion 6r disposed on the lowermost layer. 9r may be opaque.

On the B liquid crystal layer 3b side of the lower substrate 9b of the B display portion 6b, a plurality of belt-shaped data electrodes 19b extending in the vertical direction in the drawing of FIG. 3 are formed in parallel. Further, on the B liquid crystal layer 3b side of the upper substrate 9b, a plurality of belt-shaped scan electrodes 17b extending in the left and right directions in the drawing of FIG. 3 are formed in parallel. In this embodiment, the ITO transparent electrode is patterned to form a plurality of scan electrodes 17 and a plurality of data electrodes 19 in a 0.24 mm pitch stripe so that QVGA display of 320 x 240 dots can be performed.

As shown in FIG. 3, when the electrode formation surfaces of the upper and lower substrates 7b and 9b are viewed in the normal direction, the two electrodes 17b and 19b cross each other and are disposed to face each other. Each intersection region of the two electrodes 17b and 19b becomes a pixel (pixel), respectively. The pixels are arranged in a matrix to form a display screen. In addition, the number 17b, 19b shown in FIG. 4 has shown the presence area | region of the two electrodes 17b, 19b, These shapes are not suggesting.

As the material for forming the two electrodes 17b and 19b, for example, indium tin oxide (ITO) is typical, but in addition, a transparent conductive film such as indium zinc oxide (IZO), aluminum Alternatively, a metal electrode such as silicon or an optical conductive film such as amorphous silicon or bismuth silicate (BSO) can be used.

On both electrodes 17b and 19b, as a functional film, it is preferable to coat an insulating thin film and the orientation stabilization film (not shown) of liquid crystal molecules, respectively. The insulating thin film has a function of preventing a short circuit between the electrodes 17b and 19b or improving the reliability of the liquid crystal display element 1 as a gas barrier layer. As the alignment stabilizing film, organic films such as polyimide resin, polyamideimide resin, polyetherimide resin, polyvinyl butyral resin and acrylic resin, and inorganic materials such as silicon oxide and aluminum oxide can be used. In this embodiment, the orientation stabilization film is apply | coated (coated), for example on the whole board | substrate on the electrodes 17b and 19b. The orientation stabilizing film may be used in combination with the insulating thin film.

The liquid crystal layer 3b for B is enclosed between two substrates 7b and 9b by the sealing agent 21b applied to the outer periphery of the upper and lower substrates 7b and 9b. In addition, the thickness (cell spacing) of the liquid crystal layer 3b for B needs to be kept uniform. In order to maintain a predetermined cell gap, a spherical spacer made of resin or an inorganic oxide is dispersed in the liquid crystal layer 3b for B, or a plurality of columnar spacers coated with a thermoplastic resin on the surface of the liquid crystal layer 3b for B are provided. Form. Also in the liquid crystal display element 1 of this embodiment, the spacer (not shown) is inserted in B liquid crystal layer 3b, and the uniformity of cell space | interval is maintained. It is preferable that the cell gap d of the B liquid crystal layer 3b is in the range of 3 µm ≤ d ≤ 6 µm.

Since the G display part 6g and the R display part 6r have the same structure as the B display part 6b, the description is omitted. The visible light absorbing layer 15 is provided on the outer surface (rear surface) of the lower substrate 9r of the R display portion 6r. Therefore, when all of the liquid crystal layers 3b, 3g, and 3r of B, G, and R are in the focal conic state, black is displayed on the display screen of the liquid crystal display device 1. In addition, it is preferable to provide the visible light absorption layer 15 as needed.

Scan electrode drive circuit 25 in which scan IC driver ICs for driving the plurality of scan electrodes 17b, 17g, and 17r are mounted to the upper substrates 7b, 7g, and 7r. It is. Furthermore, the data electrode drive circuit 27 in which the lower substrates 9b, 9g, and 9r are mounted with data IC driver ICs for driving the plurality of data electrodes 19b, 19g, and 19r. Is connected. These drive circuits 25 and 27 transmit scan signals and data signals to predetermined scan electrodes 17b, 17g, 17r or data based on the predetermined signals outputted from the control circuit 23. It outputs to the electrodes 19b, 19g, and 19r.

In the present embodiment, since the driving voltages of the liquid crystal layers 3b, 3g, and 3r for B, G, and R can be made almost the same, the predetermined output terminal of the scan electrode driving circuit 25 Commonly connected to predetermined input terminals of the scan electrodes 17b, 17g, and 17r. Since there is no need to provide the scan electrode driving circuit 25 for each of the display portions 6r, 6g, and 6b for B, G, and R, the configuration of the driving circuit of the liquid crystal display element 1 can be simplified. Can be.

Next, the driving method of the liquid crystal display element 1 is demonstrated using FIG. 5 and FIG. 5 shows an example of a drive waveform of the liquid crystal display element 1. 5A is a drive waveform for putting the cholesteric liquid crystal in a planar state, and FIG. 5B is a drive waveform for putting the cholesteric liquid crystal in a focal conic state. 5A and 5B, the upper part of the figure shows the data signal voltage waveform Vd output from the data electrode driving circuit 27, and the middle part of the figure shows the scan signal voltage waveform Vs output from the scanning electrode driving circuit 25. In FIG. The bottom of the figure shows an applied voltage waveform Vlc applied to any one of the pixels of the liquid crystal layers 3b, 3g, and 3r for B, G, and R. In addition, in FIG. 5A and 5B, time progress is shown from the left side to the right side of a figure, and the up-down direction of a figure shows a voltage.

6 shows an example of voltage-reflectance characteristics of a cholesteric liquid crystal. The horizontal axis represents the voltage value V applied to the cholesteric liquid crystal, and the vertical axis represents the reflectance (%) of the cholesteric liquid crystal. The curve P of the solid line shown in FIG. 6 shows the voltage-reflectance characteristic of the cholesteric liquid crystal in the initial state and the planar state, and the curve FC of the dotted line shows the cholesteric liquid crystal in the focal conic state. The voltage-reflectance property of is shown.

Here, a predetermined voltage is applied to the blue (B) pixels (1, 1) of the intersection of the data electrodes 19b of the first row and the scan electrodes 17b of the first row of the B display portion 6b shown in FIG. The case will be described as an example. As shown in Fig. 5A, in the period of about 1/2 of the first half of the selection period T1 in which the scan electrodes 17b in the first row are selected, the scan is performed while the data signal voltage Vd becomes + 32V. The signal voltage Vs becomes 0V, and in the second half of the period, the scan signal voltage Vs becomes + 32V while the data signal voltage Vd becomes 0V. Therefore, a pulse voltage of ± 32 V is applied to the B liquid crystal layer 3b of the B pixels 1 and 1 between the selection periods T1. As shown in Fig. 6, when a predetermined high voltage VP100 (e.g., 32 V) is applied to the cholesteric liquid crystal to generate a strong electric field, the spiral structure of the liquid crystal molecules is completely solved, and all liquid crystal molecules are arced along the electric field direction. This is a meotropic state. Therefore, the liquid crystal molecules of the B liquid crystal layer 3b of the B pixels 1 and 1 are in the homeotropic state in the selection period T1.

When the selection period T1 ends and the non-selection period T2 is reached, the voltage of +28 V and +4 V, for example, is 1/2 of the selection period T1 in the scan electrode 17b of the first row. It is applied at the cycle of. On the other hand, a predetermined data signal voltage Vd is applied to the data electrodes 19b in the first column. In Fig. 6A, for example, voltages of +32 V and 0 V are applied to the data electrode 17b of the first row at a period of 1/2 of the selection period T1. Therefore, a pulse voltage of ± 4 V is applied to the B liquid crystal layer 3b of the B pixels 1 and 1 during the non-selection period T2. Accordingly, the electric field generated in the B liquid crystal layer 3b of the B pixels 1 and 1 becomes almost zero between the non-selection periods T2.

When the liquid crystal molecules are in the homeotropic state, when the liquid crystal applied voltage changes from VP100 (± 32 V) to VF0 (± 4 V) and the electric field suddenly becomes almost zero, the liquid crystal molecules have two helix axes 17b. And (19b) is in a spiral state that is directed in a direction substantially perpendicular to the spiral, and is a planar state that selectively reflects light according to the spiral pitch. Therefore, since the B liquid crystal layer 3b of the B pixels 1 and 1 enters a planar state and reflects light, blue color is displayed on the B pixels 1 and 1.

On the other hand, as shown in Fig. 5B, the data signal voltage Vd becomes 24 V / 8 V in the period of about 1/2 of the first half and the period of about 1/2 of the second half of the selection period T1. When the scan signal voltage Vs is 0 V / + 32 V, a pulse voltage of ± 24 V is applied to the B liquid crystal layer 3b of the B pixels 1 and 1. As shown in FIG. 6, when a predetermined low voltage VF100b (for example, 24 V) is applied to the cholesteric liquid crystal to generate a weak electric field, the spiral structure of the liquid crystal molecules is not completely solved. When the non-selection period T2 is reached, for example, a voltage of +28 V / + 4 V is applied to the scan electrode 17b of the first row at a period of 1/2 of the selection period T1, and the data electrode ( A voltage of a predetermined data signal voltage Vd (for example, +24 V / 8 V) is applied to 19b at a period of 1/2 of the selection period T1. Therefore, a pulse voltage of -4 V / + 4 V is applied to the B liquid crystal layer 3b of the B pixels 1 and 1 during the non-selection period T2. Accordingly, the electric field generated in the B liquid crystal layer 3b of the B pixels 1 and 1 becomes almost zero between the non-selection periods T2.

When the spiral structure of the liquid crystal molecules is not fully solved, when the applied voltage of the cholesteric liquid crystal changes from VF100b (± 24 V) to VF0 (± 4 V) and the electric field suddenly becomes almost zero, the liquid crystal molecules are spiraled. The axis is in a spiral state directed in a direction substantially parallel to the two electrodes 17b and 19b, and is in a focal conic state that transmits incident light. Therefore, the B liquid crystal layer 3b of the B pixels 1 and 1 enters a focal conic state and transmits light. In addition, as shown in FIG. 6, after applying a voltage of VP100 (V) to generate a strong electric field in the liquid crystal layer, the cholesteric liquid crystal can be brought into the focal conic state even if the electric field is gently removed.

The driving voltage is an example. When a pulsed phase voltage of 30 to 35 V is applied between the two electrodes 17b and 19b at room temperature for 20 ms, the cholesteric liquid crystal of the liquid crystal layer 3b for B is A selective reflection state (planar state) is obtained and when a voltage of 15 to 22 V pulses is applied for an effective time of 20 ms, a good transmission state (focal conic state) is obtained.

By driving the green (G) pixels (1, 1) and the red (R) pixels (1, 1) in the same manner as the above-described driving of the B pixels (1, 1), the three B, G, R pixels (1 , 1) can be subjected to color display on the stacked pixels (1, 1). Further, the scan electrodes 17b, 17g, and 17r from the first row to the nth row are driven in so-called linear order, and the data voltages of the data electrodes 19 are input again for each row, thereby providing a pixel. Color data for one frame (display screen) can be realized by outputting display data from all of (1, 1) to pixels (n, m).

In addition, when an electric field of medium intensity is provided to the cholesteric liquid crystal and the electric field is abruptly removed, full color display becomes possible by forming a halftone in which the planar state and the focal conic state are mixed.

Next, an example of the manufacturing method of the liquid crystal display element 1 is demonstrated easily.

ITO transparent electrodes were formed on two polycarbonate (PC) film substrates each having a length of 10 (cm) x 8 (cm) cut in length and width, and patterned by etching to form a stripe electrode having a 0.24 mm pitch. (Scanning electrode 17 or data electrode 19) is formed, respectively. Stripe-like electrodes are formed on each of the two PC film substrates to enable QVGA display of 320 x 240 dots. Next, the polyimide oriented film material is apply | coated to the thickness of about 700 GPa on each of the stripe-shaped transparent electrodes 17 and 19 on the two PC film substrates 7 and 9 by spin coating. Next, the two PC film substrates 7 and 9 to which the alignment film material was applied are baked in an oven at 90 ° C. for 1 hour to form an alignment film. Subsequently, an epoxy-based sealing material 21 is applied to a peripheral portion on one PC film substrate 7 or 9 using a dispenser to form a wall having a predetermined height.

Subsequently, a spacer 4 µm in diameter (manufactured by Sekisui Fine Chemical Co., Ltd.) is dispersed on the other PC film substrate 9 or 7. Next, two PC film board | substrates 7 and 9 are bonded together, it heats at 160 degreeC for 1 hour, and the sealing material 21 is hardened. Subsequently, after injecting the cholesteric liquid crystal LCb for B by the vacuum injection method, the injection hole is sealed with an epoxy sealing material to manufacture the B display portion 6b. By the same method, G, R display part 6g, 6r is manufactured.

4, B, G, R display parts 6b, 6g, 6r are laminated | stacked in this order from the display surface side. Subsequently, the visible light absorbing layer 15 is disposed on the rear surface of the lower substrate 9r of the R display portion 6r. Subsequently, the general-purpose STN driver having a TCP (tape carrier package) structure in the terminal portions of the scan electrodes 17 and the terminal portions of the data electrodes 19 of the stacked B, G, and R display portions 6b, 6g, and 6r. The IC is crimped and the power supply circuit and the control circuit 23 are connected. In this manner, the liquid crystal display device 1 capable of QVGA display is completed. Although not shown, electronic paper is completed by providing the input / output device and the control device (all not shown) to collectively control the completed liquid crystal display element 1.

Next, the liquid crystal composition according to the present embodiment manufactured by the above-described manufacturing method and having the above-described configuration and operation, and the display characteristics of the liquid crystal display device 1 including the same, include a contrast with a comparative example. Will be explained.

First, the material composition ratio of the conventional liquid crystal composition used as a comparative example is demonstrated using FIG. FIG. 7A shows the composition ratio of the conventional B cholesteric liquid crystal used for the B liquid crystal layer, FIG. 7B shows the composition ratio of the conventional G cholesteric liquid crystal used for the G liquid crystal layer, and FIG. 7C Shows the composition ratio of the conventional cholesteric liquid crystal for R used for the liquid crystal layer for R.

The conventional cholesteric liquid crystal for B shown in FIG. 7A is manufactured by adding the chiral material CHr 'of R body to nematic liquid crystal LCn' of predetermined weight. The content rate of chiral material CHr 'is 30 weight%. Nematic liquid crystal LCn 'is (DELTA) n = 0.20, (DELTA) epsilon = 20, and the viscosity (micrometer) = 37 (mPa * s) at room temperature. Chiral material CHr 'is (DELTA) n = 0.29 and (DELTA) epsilon = 22, and is powdery at room temperature. The dominant wavelength? B of the selective reflection of the conventional cholesteric liquid crystal for B produced is about 480 nm, and Δn = 0.23.

The conventional cholesteric liquid crystal for G shown in FIG. 7B is manufactured by adding L-type chiral material CH1 'to the nematic liquid crystal LCn' of predetermined weight. The content rate of chiral material CHl 'is 26 weight%. The nematic liquid crystal LCn 'is the same as that of the conventional cholesteric liquid crystal for B. The Δn value and the Δε value of the chiral material CH1 'are the same as those of the chiral material CHr', and are powdery at room temperature. The dominant wavelength lambda g of the selective reflection of the conventional G cholesteric liquid crystal produced is about 560 nm, and Δn = 0.22.

The conventional cholesteric liquid crystal for R shown in FIG. 7C is manufactured by adding the chiral material CHr "of R body to nematic liquid crystal LCn 'of predetermined weight. The content of chiral material CHr '' is 24% by weight. The nematic liquid crystal LCn 'is the same as that of the conventional cholesteric liquid crystal for B. Chiral material CHr "is (DELTA) n = 0.29 and (DELTA) epsilon = 25 and is powdery at room temperature. The dominant wavelength λ r of the selective reflection of the conventional cholesteric liquid crystal for R produced is about 610 nm, and Δn = 0.22. In addition, the nematic liquid crystal LCn ', chiral materials CHr', CHl ', etc. use the usual commercially available material.

As described above, the optical sensitivities (R) of the cholesteric liquid crystals for the conventional B and R are the same, and are different from the optical sensitivities (L) of the conventional cholesteric liquid crystals for the G. In addition, the content of the chiral material is higher in the conventional cholesteric liquid crystal for G than in the conventional cholesteric liquid crystal for R, and in the conventional cholesteric liquid crystal for B than in the conventional cholesteric liquid crystal for G. .

Each manufactured cholesteric liquid crystal for B, G, and R is enclosed in each liquid crystal layer of the comparative liquid crystal display element (not shown) which has the same structure as the liquid crystal display element 1 of this embodiment.

8 and 9 show the effect of improving the display characteristics of the liquid crystal display element 1 according to the present embodiment, compared with the liquid crystal display element for comparison.

8 shows the reflectance (scattering) of the liquid crystal layer 3r for R in the focal conic state. The horizontal axis represents the wavelength of the reflected light (nm), and the vertical axis represents the scattering (%). Curve (A) in the figure shows the scattering characteristic of the liquid crystal layer 3r for R of the liquid crystal display element 1 of this embodiment, and curve (B) in the figure shows the scattering of the R liquid crystal layer of the conventional liquid crystal display element. Characteristics. The Δn value of the R liquid crystal layer 3r of the liquid crystal display element 1 of the present embodiment is 0.23, and the Δn value of the R liquid crystal layer of the conventional liquid crystal display device is 0.29, which is almost equivalent. However, as shown in FIG. 8, the reflectance in the focal conic state of the liquid crystal layer 3r for R of the liquid crystal display element 1 of this embodiment, so-called scattering, is for conventional R in the whole range of a measurement wavelength. It turns out that it is about 30 to 60% lower than scattering in a liquid crystal layer.

FIG. 9 compares and shows the scattering characteristics of each liquid crystal layer for B, G, and R in the focal conic state of the liquid crystal display element 1 and the conventional liquid crystal display element of the present embodiment. The horizontal axis represents the liquid crystal display element 1 (new liquid crystal) and the conventional liquid crystal display element (conventional liquid crystal) of the present embodiment, and the vertical axis represents scattering (white plate ratio) (%). In the drawings,? Denotes scattering characteristics of the liquid crystal layer for R, and? Denotes scattering characteristics of the liquid crystal layer for G, and? Denotes scattering characteristics of the liquid crystal layer for G in the figure. As shown in FIG. 9, it turns out that the scattering in the focal conic state is reduced in the liquid crystal display element 1 of this embodiment compared with the conventional liquid crystal display element in all liquid crystal layers for B, G, and R. As shown in FIG. have. Specifically, in the liquid crystal layer 3r for R, the scattering is reduced by about 60% as compared with the prior art. Also in the liquid crystal layers 3g and 3b for G and B, scattering is reduced by about 10% compared with the prior art. The scattering in the liquid crystal layer for B is reduced because the Δn value of the chiral material is smaller than the Δn value of the nematic liquid crystal in the liquid crystal display device 1 of the present embodiment. Empirically it has been found that it can be reduced.

In addition, the reflectance is measured by measuring the luminous reflectance (Y value) using a reflection type spectrometer. The smaller the Y value at the time of discoloration, the better the transparent and black display. The higher the Y value at the time of coloring, the better the color display. Contrast is calculated as (Y value in planar state / Y value in focal conic).

According to this embodiment, the following effects can be obtained.

First, the higher the content of the chiral material, the more strongly the liquid crystal molecules are twisted, the shorter the pitch of the spirals, and the shorter the wavelength of the reflected light in the planar state. Therefore, the content rate of the chiral material of the conventional cholesteric liquid crystal was G use lower than B use, and R use lower than G use (refer FIG. 7).

By the way, as shown in FIG. 1, in the liquid crystal layer for R using the cholesteric liquid crystal whose content rate of a chiral material is comparatively low, the problem that the direction of the spiral axis of the liquid crystal molecule 33b of a bulk region, and the nonuniformity of a spiral structure arises large. It was.

Therefore, in the present embodiment, the cholesteric liquid crystal LCr for R having a chiral material content higher than the chiral material content of the G cholesteric liquid crystal LCg (see FIG. 2A) capable of propagating the orientation regulating force to the bulk region (see FIG. 2C). ) Was used for the liquid crystal layer 43r for R. As a result, the alignment regulating force can be propagated to the bulk region, and a sufficient focal conic state can be generated almost uniformly in the cell thickness direction. The director of the liquid crystal molecules 33 of the R liquid crystal layer 43r is substantially perpendicular to the substrate surfaces of the upper and lower substrates 7r and 9r not only in the vicinity of the substrate interface but also in the bulk region, and rotates in the direction of the substrate surface in turn. As a result, a spiral structure is formed, and the spiral axis of the spiral structure is substantially parallel to the substrate surface.

In addition, since the chiral material contained in the cholesteric liquid crystal LCr for R contains two types of optical isomers having different optical selectivities at a predetermined ratio, the spiral pitch required for selective reflection of red color can be obtained.

As is clear from FIG. 2 and FIG. 7, in the liquid crystal display device 1 according to the present embodiment, the content of the chiral material is inversely different from that of the conventional composition. In addition, the liquid crystal layer for R increases and at the same time, the R liquid crystal layer for reflecting the light having the longest wavelength includes the R- and L-chiral materials. In this way, by increasing the content of the chiral material in the liquid crystal layer for R, in which scattering of light in the focal conic state is strong, scattering of light in the liquid crystal layer for R can be collectively reduced in a wide wavelength range. Therefore, the color balance and contrast of each liquid crystal layer for B, G, and R can fully be improved. Further, by using a cholesteric liquid crystal formed of a material in which the refractive index anisotropy Δn value of the nematic liquid crystal is larger than the Δn value of the chiral material, the color purity and contrast of the display color can be improved more preferably. Moreover, since the drive voltage of each liquid crystal layer for B, G, and R can be matched favorably, the structure of the drive circuit of a liquid crystal display element can be simplified.

As described above, in the cholesteric liquid crystal of the present embodiment, noise reflection in the focal conic state is suppressed satisfactorily, so that color purity and contrast are sufficiently improved. Therefore, the liquid crystal display element 1 using this cholesteric liquid crystal and the electronic paper using the same can implement | achieve the color image display with a clear, favorable contrast, and a wide color reproduction range.

In addition, the liquid crystal composition, liquid crystal display element, and electronic paper which concerns on this invention are not limited to the said embodiment.

For example, the composition ratio of the cholesteric liquid crystal used for the liquid crystal display element 1 has the highest content rate of the chiral material of the cholesteric liquid crystal for R, and the cholesteric liquid crystal for R has two types of optical which differ in opticality. It is preferable to contain an isomer (chiral material of R body and L body). Therefore, the G cholesteric liquid crystal may contain only one of the chiral materials R or L.

The composition ratio of the cholesteric liquid crystal LCb, LCg, LCr shown in the said embodiment is not limited to this. It is preferable that the content rate x of the chiral material contained in the nematic liquid crystal (0.18 <= (DELTA) n <= 0.24) of the cholesteric liquid crystal which comprises each liquid crystal layer for B, G, and R is 20 weight% <= x <60 weight%. . Although various conventionally known nematic liquid crystals can be used, the value of the refractive index anisotropy Δn of the nematic liquid crystal is 0.18 ≦ Δn ≦ 0.24, and the dielectric anisotropy Δε is preferably 20 ≦ Δε ≦ 50. When the dielectric anisotropy Δε of the nematic liquid crystal is 20 or more, the selection range of the chiral material that can be used is widened.

It is preferable that the dielectric anisotropy Δε as the cholesteric liquid crystal is 20 ≦ Δε ≦ 50. If the dielectric anisotropy Δε of the cholesteric liquid crystal is too lower than the above range, the driving voltage is high. On the contrary, if the dielectric anisotropy Δε is too high above the range, the stability and reliability of the liquid crystal display element are poor. As a result, image defects and image noise tend to occur in the liquid crystal display element. In addition, the resistivity R as the cholesteric liquid crystal is preferably in the range of 10 ¹⁰ ≤ R ≤ ^{10 13} (Ωcm), and the relative dielectric constant ε is 5≤ε≤15 in the planar state and 10≤ε≤ in the focal conic state. It is preferable that it is 25. In addition, since the lower viscosity can suppress the voltage increase and the lower contrast at low temperature, the viscosity μ at room temperature is preferably in the range of 20 ≦ μ ≦ 1200 (mPa · s).

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows typically the state of the liquid crystal molecule in the focal conic state of each liquid crystal layer for B, G, and R in the related art.

It is a figure which shows the composition ratio of the material contained in the liquid crystal composition by one Embodiment of this invention.

3 is a diagram showing a schematic configuration of a liquid crystal display device 1 according to an embodiment of the present invention.

4 is a diagram schematically showing a cross-sectional structure of a liquid crystal display element 1 according to an embodiment of the present invention.

5 is a diagram illustrating an example of a drive waveform of the liquid crystal display device 1 according to the embodiment of the present invention.

It is a figure which shows an example of the voltage-reflectivity characteristic of the liquid crystal composition by one Embodiment of this invention.

It is a figure which shows the composition ratio of the material contained in the conventional liquid crystal composition.

It is a figure which shows the reflectance (scattering) of the liquid crystal layer for R in the focal conic state of the liquid crystal display element 1 by one Embodiment of this invention.

It is a figure which shows the comparative example of scattering of each liquid crystal layer for B, G, and R of the liquid crystal display element 1 and the conventional liquid crystal display element by one Embodiment of this invention.

It is a figure which shows typically the cross-sectional structure of the conventional liquid crystal display element which can display full color.

It is a figure which shows typically the cross-sectional structure of 1 liquid crystal layer of the conventional liquid crystal display element.

It is a figure which shows an example of the reflection spectrum in the planar state of the conventional liquid crystal display element.

It is a figure which shows the relationship between the refractive index anisotropy (DELTA) n of the conventional liquid crystal display element, and the reflection of the light in a liquid crystal layer.

<Description of the code>

1: liquid crystal display element

3b, 43b: liquid crystal layer for B

3g, 43g: liquid crystal layer for G

3r, 43r: liquid crystal layer for R

6b, 46b: B display section

6g, 46g: G display

6r, 46r: R display section

7b, 7g, 7r: upper substrate

9b, 9g, 9r: lower substrate

47, 49: substrate

15: visible light absorbing layer

17r, 17g, 17b: scan electrode

19r, 19g, 19b: data electrode

21b, 21g, 21r: sealing material

23: control circuit

25: scan electrode driving circuit

27: data electrode driving circuit

31: liquid crystal layer

33, 33b, 33s: liquid crystal molecules

41: pulse voltage source

Claims (17)

A first liquid crystal layer comprising a first chiral material contained in the nematic liquid crystal to form a cholesteric phase so as to reflect light of a first wavelength in a planar state; A second chiral material which is contained in the nematic liquid crystal at a content higher than the content of the first chiral material to form a cholesteric phase so as to reflect light of a second wavelength longer than the first wavelength in a planar state; It has a 2nd liquid crystal layer, The liquid crystal display element characterized by the above-mentioned. The liquid crystal display device according to claim 1, wherein the second chiral material comprises two kinds of optical isomers having different optical selectivities. The cholesteric phase according to claim 1 or 2, wherein the cholesteric phase is contained in the nematic liquid crystal at a content higher than that of the second chiral material so as to reflect light of a third wavelength longer than the second wavelength in a planar state. It further has a 3rd liquid crystal layer provided with the 3rd chiral material to form, The liquid crystal display element characterized by the above-mentioned. 4. A liquid crystal display device as claimed in claim 3, wherein said third chiral material comprises two kinds of optical isomers having different optical selectivities. The liquid crystal display device according to claim 3 or 4, wherein the light of the first wavelength is blue, the light of the second wavelength is green, and the light of the third wavelength is red. The liquid crystal display device according to any one of claims 3 to 5, wherein the first to third liquid crystal layers are sealed between a pair of different substrates, respectively. The said 1st liquid crystal layer, the said 2nd liquid crystal layer, and the said 3rd liquid crystal layer are laminated | stacked in this order from the display surface side, The any one of Claims 3-6 characterized by the above-mentioned. Liquid crystal display device. 8. The liquid crystal display according to any one of claims 3 to 7, wherein the opticality in the second liquid crystal layer in a planar state is different from the opticality in the first and third liquid crystal layers. device. The liquid crystal display device according to any one of claims 3 to 8, wherein a cell gap d of each of the first to third liquid crystal layers is 3 µm ≤ d ≤ 6 µm. The said 1st-3rd liquid crystal layer is a focal conic state in any one of Claims 3-9 on the opposite side to the light incident side of the said pair of board | substrate which seals the said 3rd liquid crystal layer. The light absorption layer which absorbs light is arrange | positioned so that black may be displayed in the liquid crystal display element characterized by the above-mentioned. The liquid crystal display device according to any one of claims 3 to 10, wherein the content x of the first to third chiral materials is 20% by weight x 60% by weight. The liquid crystal display device according to any one of claims 1 to 11, wherein a value of the refractive index anisotropy Δn of the nematic liquid crystal is 0.18 ≦ Δn ≦ 0.24. The liquid crystal display device according to claim 12, wherein the refractive anisotropy Δn of the first to third chiral materials is smaller than Δn of the nematic liquid crystal. In an electronic paper having a display unit for displaying a predetermined image, The said display part is equipped with the liquid crystal display element in any one of Claims 1-13, The electronic paper characterized by the above-mentioned. A nematic liquid crystal and a chiral material contained in the nematic liquid crystal to form a cholesteric phase, The said chiral material has a content rate higher than the content rate which reflects the light of the said 1st wavelength so that it may reflect the light of the 2nd wavelength longer than a 1st wavelength in a planar state. 16. The liquid crystal composition according to claim 15, wherein the chiral material comprises two kinds of optical isomers having different photosensitivity. A liquid crystal composition comprising a nematic liquid crystal and a chiral material added in the nematic liquid crystal to have a refractive index anisotropy smaller than that of the nematic liquid crystal and to form a cholesteric phase.

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