JP4293882B2 - Broadband cholesteric liquid crystal film manufacturing method, circularly polarizing plate, linearly polarizing element, illumination device, and liquid crystal display device - Google Patents

Description

  The present invention relates to a method for producing a broadband cholesteric liquid crystal film. The broadband cholesteric liquid crystal film of the present invention is useful as a circularly polarizing plate (reflection type polarizer). The present invention also relates to a linearly polarizing element, an illumination device, and a liquid crystal display device using the circularly polarizing plate.

  In general, a liquid crystal display has a structure in which liquid crystal is injected between glass plates on which transparent electrodes are formed, and polarizers are arranged before and after the glass plate. A polarizer used in such a liquid crystal display is produced by adsorbing iodine, a dichroic dye, or the like on a polyvinyl alcohol film and stretching it in a certain direction. The polarizer itself thus produced absorbs light oscillating in one direction and passes only light oscillating in the other direction to produce linearly polarized light. For this reason, the efficiency of the polarizer cannot theoretically exceed 50%, which is the biggest factor for reducing the efficiency of the liquid crystal display. Also, due to this absorbed light, if the light source output is increased to a certain extent, the liquid crystal display device will display due to the heat generated by the heat conversion of the absorbed light, or the polarizer will be destroyed, or the liquid crystal layer inside the cell will be affected by heat. It has caused adverse effects such as deterioration of quality.

  A cholesteric liquid crystal having a circularly polarized light separation function has a selective reflection characteristic that reflects only circularly polarized light whose wavelength is the spiral pitch of the liquid crystal, with the rotational direction of the spiral of the liquid crystal coincident with the circular polarization direction. By using this selective reflection characteristic, only specific circularly polarized light of natural light in a fixed wavelength band is transmitted and separated, and the rest is reflected and reused, whereby a highly efficient polarizing film can be manufactured. At this time, the transmitted circularly polarized light is converted into linearly polarized light by passing through the λ / 4 wavelength plate, and the direction of this linearly polarized light is aligned with the transmission direction of the absorbing polarizer used in the liquid crystal display, thereby achieving high transmittance. A liquid crystal display device can be obtained. That is, when a cholesteric liquid crystal film is used as a linearly polarizing element in combination with a λ / 4 wavelength plate, there is theoretically no loss of light. Therefore, when a conventional absorption polarizer that absorbs 50% of light is used alone. In comparison, theoretically, the brightness can be improved by a factor of two.

However, the selective reflection characteristics of cholesteric liquid crystals are limited to a specific wavelength band, and it is difficult to cover the entire visible light range. The selective reflection wavelength region width Δλ of the cholesteric liquid crystal is
Δλ = 2λ · (ne−no) / (ne + no)
no: Refractive index of cholesteric liquid crystal molecules with respect to normal light ne: Refractive index of cholesteric liquid crystal molecules with respect to extraordinary light λ: Represented by the center wavelength of selective reflection, which depends on the molecular structure of the cholesteric liquid crystal itself. If ne-no is increased from the above formula, the selective reflection wavelength region width Δλ is widened, but ne-no is usually 0.3 or less. When this value is increased, other functions as liquid crystal (alignment characteristics, liquid crystal temperature, etc.) are insufficient and practical use is difficult. Therefore, in practice, the selective reflection wavelength region width Δλ is about 150 nm at the maximum. Many of the practically usable cholesteric liquid crystals were only about 30 to 100 nm.

The selective reflection center wavelength λ is
λ = (ne + no) P / 2
P: It is represented by the helical pitch length required for one rotation of the cholesteric liquid crystal. If the pitch is constant, it depends on the average refractive index and the pitch length of the liquid crystal molecules.

  Therefore, in order to cover the entire visible light region, a plurality of layers having different selective reflection center wavelengths are laminated, or the pitch length is continuously changed in the thickness direction to form an existence distribution of the selective reflection center wavelengths themselves. It was.

  For example, there is a method of continuously changing the pitch length in the thickness direction (see, for example, Patent Document 1, Patent Document 2, Patent Document 3, and Patent Document 4). In this method, when the cholesteric liquid crystal composition is cured by ultraviolet exposure, the composition ratio of the liquid crystal compositions having different reaction rates is obtained by making a difference in the exposure intensity on the exposed surface side and the exit surface side and by making a difference in the polymerization rate. The change is provided in the thickness direction.

  The point of this method is to take a large difference in exposure intensity between the exposure surface side and the exit surface side. Therefore, in many cases of the above-mentioned prior art examples, a method of mixing an ultraviolet absorber with a liquid crystal composition, generating absorption in the thickness direction, and amplifying a difference in exposure amount due to an optical path length has been adopted. .

  However, the technique of continuously changing the pitch length as in Patent Document 1 requires a liquid crystal layer thickness of about 15 to 20 μm that is necessary for the function to be exhibited. Cost increase was inevitable due to the need for more. Further, the exposure time is required for about 1 to 60 minutes, and a long production line with an exposure line length of 10 to 600 m is required to obtain a line speed of 10 m / min. If the line speed is lowered, the line length can be reduced, but the production speed is inevitably lowered.

  As described in Patent Document 1, the cholesteric pitch is changed by a composition ratio change consisting of a mass transfer due to a difference in ultraviolet exposure intensity in the thickness direction for changing the pitch length in the thickness direction and a polymerization rate difference associated therewith. This is because it is difficult to form a rapid pitch change due to a theoretical problem to be controlled. In Patent Document 1, since the pitch length is different by about 100 nm between the short pitch side and the long pitch side, it is necessary to change the composition ratio greatly. To realize this, a considerable liquid crystal thickness, weak UV irradiation, and a long exposure time are required. is necessary.

  In Patent Document 3, the mobility of the substance whose pitch is changed is better than that of the material example used in Patent Document 1, so that film formation can be performed with an exposure amount of about 1 minute. However, even in this case, a thickness of 15 μm is required.

  In Patent Document 2, the temperature conditions of the primary exposure and the secondary exposure are changed, and the time necessary for the composition ratio to change in the thickness direction is separately provided in a dark place. When trying to do so, the waiting time for mass transfer due to this temperature change needs to be about 120 minutes.

  The technique of continuously changing the pitch length as in Patent Document 4 requires a liquid crystal layer thickness of about 15 to 20 μm necessary for the function to be manifested, and many expensive liquid crystals are required in addition to the problem of precise coating of the liquid crystal layer. Therefore, the cost increase was inevitable. In Patent Document 4, when the cholesteric liquid crystal composition is cured by ultraviolet exposure from the side opposite to the substrate (air interface side), the composition is obtained by making a difference in exposure intensity between the exposure surface side and the exit surface side due to oxygen inhibition. The ratio change is changed in the thickness direction.

  However, in FIG. 4 in Example 1 of Patent Document 4, although the selective reflection wavelength is widened, the slope of the transmittance curve is gentle on both the short wavelength end side and the long wavelength side, so that it covers substantially the entire visible light range. Has not reached. In FIG. 6) in Example 2 of Patent Document 4, although the slopes of both wavelength ends are steep, the band itself is narrow.

In particular, when this type of polarizing element is used in a liquid crystal display device, it is necessary to ensure sufficiently flat transmittance / reflectance characteristics with respect to three wavelengths of 435 nm, 545 nm, and 615 nm, which are emission spectra of a backlight light source. . The broadening range obtained by the methods of Examples 1 and 2 described in Patent Document 4 was insufficient for covering the emission line spectra of 435 nm and 615 nm in either case. In such a case, it is difficult to obtain a white color of transmitted light, and it is not used for a liquid crystal display device or the like.
JP-A-6-281814 Japanese Patent No. 3272668 JP 11-248943 A JP 2002-286935 A

  The applicant has filed Japanese Patent Application No. 2001-339632 for the above problem. In this application, the liquid crystal composition applied to the alignment substrate is irradiated with ultraviolet rays from the alignment substrate. From this, polymerization is started from the surface that is not easily affected by the inhibition of polymerization by oxygen in contact with the alignment substrate, and the UV irradiation intensity distribution is formed in the thickness direction by taking advantage of the absorption by the molar absorption coefficient of the liquid crystal layer, thereby inhibiting oxygen inhibition. By reducing the effective irradiation amount of ultraviolet rays on the air surface side that receives a large amount of liquid crystal, a larger liquid crystal reaction rate gradient and composition concentration distribution gradient than conventional ones are formed. In this way, by making a difference in exposure intensity between the exposure surface side and the exit surface side, a large change in the thickness direction of the cholesteric pitch length was successfully achieved. In this application, the maximum selective reflection wavelength bandwidth was as wide as 296 nm.

In the case of the said application, the wavelength band of about 400-700 nm is covered. These wavelength bands cover the light source spectrum. These provide good circularly polarized reflection characteristics in the vicinity of normal incidence. On the other hand, it was not a sufficient wavelength band at the time of oblique incidence. The selective reflection wavelength λ at oblique incidence is
λ = npcos {sin ⁻¹ (sin θ / n)}
n = average refractive index of the liquid crystal p = cholesteric pitch length θ = incident angle, so that when obliquely incident, the selective reflection wavelength is shifted to the shorter wavelength side than when vertically incident. For this reason, in order to function effectively with respect to obliquely incident light, it is necessary to function in a long wavelength region.

  An object of the present invention is to provide a method capable of producing a broadband cholesteric liquid crystal film having a broadband reflection band even in a long wavelength region.

  Another object of the present invention is to provide a circularly polarizing plate using a broadband cholesteric liquid crystal film obtained by the production method. Furthermore, it aims at providing the linearly polarizing element, the illuminating device, and the liquid crystal display device which used the said circularly-polarizing plate.

  As a result of intensive studies to solve the above-mentioned problems, the present inventors have found that a broadband cholesteric liquid crystal film capable of achieving the above object can be obtained by the following production method, and have completed the present invention. That is, the present invention is as follows.

1. A reflection bandwidth of 200 nm or more, including a step of applying a liquid crystal mixture containing a polymerizable mesogenic compound (A) and a polymerizable chiral agent (B) to an alignment substrate, and a step of polymerizing and curing the liquid crystal mixture by irradiating with ultraviolet rays. A method for producing a broadband cholesteric liquid crystal film having
The ultraviolet polymerization step includes
In a state where the liquid crystal mixture is in contact with a gas containing oxygen, UV irradiation is performed from the alignment substrate side at an ultraviolet irradiation intensity of 20 to 200 mW / cm ² at a temperature of 20 ° C. or higher for 0.2 to 5 seconds. Step (1) to perform,
Next, in a state where the liquid crystal layer is in contact with a gas containing oxygen, the temperature of the step (1) is higher than the step (1) and the temperature rise rate is 2 ° C./second or more until the temperature reaches 60 ° C. (2) a step of irradiating ultraviolet rays from the alignment substrate side for 10 seconds or more at a lower ultraviolet irradiation intensity than
Next, a method for producing a broadband cholesteric liquid crystal film, comprising the step (3) of irradiating ultraviolet rays in the absence of oxygen.

  2. 2. The method for producing a broadband cholesteric liquid crystal film according to 1 above, wherein the pitch length of the cholesteric liquid crystal film is changed so as to be continuously narrowed from the alignment substrate side.

3. 3. The broadband cholesteric liquid crystal film as described in 1 or 2 above, wherein the polymerizable mesogenic compound (A) has one polymerizable functional group and the polymerizable chiral agent (B) has two or more polymerizable functional groups. Manufacturing method.
4). The molar extinction coefficient of the polymerizable mesogenic compound (A) is the molar extinction coefficient of the polymerizable mesogenic compound (A).
0.1 to 500 dm ³ mol ⁻¹ cm ⁻¹ @ 365 nm,
10-30000 dm ³ mol ⁻¹ cm ⁻¹ @ 334 nm, and
1000~100000dm ³ mol ^-1 cm ^-1 @ manufacturing method of broad band cholesteric liquid crystal film according to any one of the above 1 to 3, characterized in that it is a 314 nm.

  5). The polymerizable mesogenic compound (A) has the following general formula (1):

（式中、Ｒ₁ 〜Ｒ₁₂は同一でも異なっていてもよく、−Ｆ、−Ｈ、−ＣＨ₃ 、−Ｃ₂ Ｈ₅ または−ＯＣＨ₃ を示し、Ｒ₁₃は−Ｈまたは−ＣＨ₃ を示し、Ｘ₁ は一般式（２）：
−（ＣＨ₂ ＣＨ₂ Ｏ）_a −（ＣＨ₂ ）_b −（Ｏ）_C −、を示し、Ｘ₂ は−ＣＮまたは−Ｆを示す。但し、一般式（２）中のａは０〜３の整数、ｂは０〜１２の整数、ｃは０または１であり、かつａ＝１〜３のときはｂ＝０、ｃ＝０であり、ａ＝０のときはｂ＝１〜１２、ｃ＝０〜１である。）で表される化合物であることを特徴とする上記１〜４のいずれかに記載の広帯域コレステリック液晶フィルムの製造方法。

(In the formula, R _{1 to} R ₁₂ may be the same or different and represent —F, —H, —CH ₃ , —C ₂ H ₅ or —OCH ₃ , and R ₁₃ represents —H or —CH ₃ . X ₁ is represented by the general formula (2):
_{- (CH 2 CH 2 O)} a - (CH 2) b - (O) C -, indicates, X ₂ represents a -CN or -F. In the general formula (2), a is an integer of 0 to 3, b is an integer of 0 to 12, c is 0 or 1, and when a = 1 to 3, b = 0 and c = 0. Yes, when a = 0, b = 1 to 12, and c = 0 to 1. The method for producing a broadband cholesteric liquid crystal film according to any one of the above 1 to 4, wherein the compound is represented by the formula:

6). A circularly polarizing plate using a broadband cholesteric liquid crystal film having a reflection bandwidth of 200 nm or more obtained by the production method according to any one of 1 to 5 above.

7). Between at least two reflective polarizers (a) in which the wavelength bands of selective reflection of polarized light overlap each other,
A retardation layer (b) having a front phase difference (normal direction) of substantially zero and a phase difference of λ / 8 or more with respect to incident light that is inclined by 30 ° or more with respect to the normal direction is disposed. A polarizing element,
A polarizing element, wherein the reflective polarizer (a) is the circularly polarizing plate described in 6 above.

  8). 8. The polarizing element according to 7 above, wherein the selective reflection wavelengths of at least two layers of the reflective polarizer (a) overlap each other in a wavelength range of 550 nm ± 10 nm.

9. A phase difference layer (b) in which the planar orientation of a cholesteric liquid crystal phase having a selective reflection wavelength region other than a visible light region is fixed;
A fixed liquid crystal in a homeotropic alignment state;
A fixed discotic liquid crystal nematic phase or columnar phase alignment state,
A biaxially oriented polymer film, or
9. The polarizing element as described in 7 or 8 above, wherein the inorganic layered compound having negative uniaxiality is oriented and fixed so that the optical axis is in the normal direction of the surface.

  10. A linearly polarizing element, wherein a λ / 4 plate is laminated on the circularly polarizing plate according to 6 or the polarizing element according to any one of 7 to 9, and linearly polarized light is obtained by transmission.

  11. 11. The linearly polarizing element as described in 10 above, obtained by laminating a cholesteric liquid crystal film, which is a circularly polarizing plate, on a λ / 4 plate so that the pitch length is continuously narrowed.

  12 12. The linearly polarizing element as described in 10 or 11 above, wherein the λ / 4 plate is a retardation plate that is biaxially stretched to correct the phase difference of obliquely incident light and to improve the viewing angle.

  13. 12. The linearly polarizing element as described in 10 or 11 above, wherein the λ / 4 plate is a liquid crystal polymer type retardation plate obtained by applying and fixing nematic liquid crystal or smectic liquid crystal.

  14 When the λ / 4 plate has an in-plane main refractive index of nx and ny and a thickness direction main refractive index of nz, the Nz coefficient defined by the formula: (nx−nz) / (nx−ny) is The linearly polarizing element as described in any one of 10 to 13 above, which satisfies -0.5 to -2.5.

  15. 15. A linearly polarizing element, wherein a λ / 2 plate is further laminated on the λ / 4 plate of the linearly polarizing element as described in any one of 10 to 14 above.

  16. A linearly polarizing element, wherein an absorption type polarizer in which the transmission axis of the linearly polarizing element according to any one of the above 10 to 15 is aligned with the transmission axis direction is laminated on the λ / 4 plate side of the linearly polarizing element. .

  17. The circularly polarizing plate according to 6 above, the polarizing element according to any one of 7 to 9 above, or the linearly polarizing element according to any one of 10 to 16 above is provided on the front side of a surface light source having a reflective layer on the back side. A lighting device characterized by that.

  18. 18. A liquid crystal display device comprising a liquid crystal cell on the light emitting side of the illumination device as set forth in 17 above.

  19. 19. The viewing angle widening liquid crystal display device according to claim 18, wherein a viewing angle widening film for diffusing light on the viewing side that has passed through the liquid crystal cell is disposed on the viewing side with respect to the liquid crystal cell.

  20. 20. The viewing angle widening liquid crystal display device as described in 19 above, wherein a diffusion plate substantially free from backscattering and depolarization is used as the viewing angle widening film.

  As described above, in the present invention, in order to broaden the reflection band, the first exposure is performed with the illuminance / irradiation temperature of ultraviolet irradiation from the alignment substrate side in a state where the liquid crystal mixture is in contact with a gas containing oxygen. The process (1) and the process (2) that is the second exposure use different conditions. Thereby, finer control of the reaction behavior of the polymerizable liquid crystal mixture can be realized, and a broadband cholesteric liquid crystal film can be obtained at a production rate that is higher in efficiency than in the past.

  That is, the ultraviolet irradiation conditions are the first irradiation intensity> the second irradiation intensity, and the first irradiation time <the second irradiation time. In the second ultraviolet irradiation, the temperature is rapidly increased to a predetermined set temperature (reached temperature). Due to the difference in irradiation intensity, the amount of radicals generated by the UV reaction of the photoinitiator in the liquid crystal composition per unit time is greatly changed between the first UV irradiation and the second UV irradiation. In the first ultraviolet irradiation, a large amount of radicals are instantaneously formed under monomer-rich conditions at the initial stage of reaction, and a large inclination in the thickness direction is formed in the radical distribution by oxygen inhibition and absorption of the liquid crystal composition. As a result, a polymer / oligomer having an average molecular weight of about 10,000 to 500,000 is formed, and a concentration distribution is formed in the thickness direction. Moreover, in this case, since the reaction rates of the polymerizable mesogenic compound (A) and the polymerizable chiral agent (B) in the liquid crystal composition are different, the polymerization ratio is different in the thickness direction. For this reason, a surface rich in the polymerizable chiral agent (B) has a short cholesteric pitch and a long reverse direction surface. As a result, a cholesteric liquid crystal film having a broadband reflection wavelength as a whole is obtained.

  The broadband cholesteric liquid crystal film thus obtained functions as a broadband circularly polarizing reflector, has optical properties equivalent to those of Patent Documents 1 to 4 and the like, and has a larger number of layers than the conventional manufacturing method. The thickness can be reduced by the reduction, and can be easily manufactured in a short time, and the cost can be reduced by improving the production speed.

  The broadband cholesteric liquid crystal film obtained by the production method of the present invention has a wide reflection bandwidth of 200 nm or more at the selective reflection wavelength, and has a broadband reflection bandwidth. The reflection bandwidth is preferably 300 nm or more, more preferably 400 nm or more, and more preferably 450 nm. Moreover, it is preferable to have a reflection bandwidth of 200 nm or more in the visible light region, particularly in the wavelength region of 400 to 900 nm.

  The circularly polarized light reflector having a wide reflection band even in a long wavelength region is an important problem for obtaining a good viewing angle characteristic of the liquid crystal display device. In order to prevent the transmitted light from being colored in a practical viewing angle range, the long wavelength end of selective reflection needs to reach 800 to 900 nm. According to the production method of the present invention, a broadband cholesteric liquid crystal film having a reflection band in such a long wavelength region can be obtained. Such a broadband cholesteric liquid crystal film is not only used as a reflective polarizer for obtaining high brightness, but also in the case of a polarizing element prepared in combination with other optical elements such as a phase difference plate, as well as oblique incidence other than the front. Stable optical properties with respect to light rays are required.

  The broadband cholesteric liquid crystal film of the present invention is obtained by ultraviolet polymerization of a liquid crystal mixture containing a polymerizable mesogenic compound (A) and a polymerizable chiral agent (B).

  As the polymerizable mesogenic compound (A), those having at least one polymerizable functional group and having a mesogenic group composed of a cyclic unit or the like are preferably used. Examples of the polymerizable functional group include an acryloyl group, a methacryloyl group, an epoxy group, and a vinyl ether group. Among these, an acryloyl group and a methacryloyl group are preferable. Further, by using a compound having two or more polymerizable functional groups, a crosslinked structure can be introduced to improve durability. Examples of the cyclic unit serving as a mesogenic group include biphenyl, phenylbenzoate, phenylcyclohexane, azoxybenzene, azomethine, azobenzene, phenylpyrimidine, diphenylacetylene, diphenylbenzoate, and bicyclohexane. Cyclohexylbenzene, terphenyl and the like. In addition, the terminal of these cyclic units may have substituents, such as a cyano group, an alkyl group, an alkoxy group, a halogen group, for example. The mesogenic group may be bonded via a spacer portion that imparts flexibility. Examples of the spacer portion include a polymethylene chain and a polyoxymethylene chain. The number of repeating structural units forming the spacer portion is appropriately determined depending on the chemical structure of the mesogenic portion, but the repeating unit of the polymethylene chain is 0 to 20, preferably 2 to 12, and the repeating unit of the polyoxymethylene chain is 0 to 0. 10, preferably 1-3.

The molar extinction coefficient of the polymerizable mesogenic compound (A) is 0.1 to 500 dm ³ mol ⁻¹ cm ⁻¹ @ 365 nm, 10 to 30,000 dm ³ mol ⁻¹ cm ⁻¹ @ 334 nm, and 1000 to 100,000 dm ^3. it is preferable that the mol ^-1 cm ^-1 @ 314nm. Those having the molar extinction coefficient have ultraviolet absorbing ability. Molar extinction coefficient is ^{0.1~50dm 3 mol -1 cm -1 @ 365nm} , a ^{50~10000dm 3 mol -1 cm -1 @ 334nm} , is 10000~50000dm ³ mol ^-1 cm ^-1 @ 314nm More preferred. Molar extinction coefficient is ^{0.1~10dm 3 mol -1 cm -1 @ 365nm} , a ^{1000~4000dm 3 mol -1 cm -1 @ 334nm} , at 30000~40000dm ³ mol ^-1 cm ^-1 @ 314nm More preferably. Molar extinction coefficient of ^{0.1dm 3 mol -1 cm -1 @ 365nm} , 10dm 3 mol -1 cm -1 @ 334nm, 1000dm 3 mol -1 cm -1 @ without stick 314nm smaller than sufficient polymerization rate difference It is difficult to increase the bandwidth. On the other ^{hand, 500dm 3 mol -1 cm -1 @} 365nm, 30000dm 3 mol -1 cm -1 @ 334nm, 100000dm 3 mol -1 cm -1 @ If 314nm greater than the polymerization curing to not proceed completely does not end There is. The molar extinction coefficient is a value measured from the absorbance at 365 nm, 334 nm, and 314 nm obtained by measuring the spectrophotometric spectrum of each material.

  The polymerizable mesogenic compound (A) having one polymerizable functional group is, for example, the following general formula 1

（式中、Ｒ₁ 〜Ｒ₁₂は同一でも異なっていてもよく、−Ｆ、−Ｈ、−ＣＨ₃ 、−Ｃ₂ Ｈ₅ または−ＯＣＨ₃ を示し、Ｒ₁₃は−Ｈまたは−ＣＨ₃ を示し、Ｘ₁ は一般式（２）：
−（ＣＨ₂ ＣＨ₂ Ｏ）_a −（ＣＨ₂ ）_b −（Ｏ）_C −、を示し、Ｘ₂ は−ＣＮまたは−Ｆを示す。但し、一般式（２）中のａは０〜３の整数、ｂは０〜１２の整数、ｃは０または１であり、かつａ＝１〜３のときはｂ＝０、ｃ＝０であり、ａ＝０のときはｂ＝１〜１２、ｃ＝０〜１である。）で表される化合物があげられる。

(In the formula, R _{1 to} R ₁₂ may be the same or different and represent —F, —H, —CH ₃ , —C ₂ H ₅ or —OCH ₃ , and R ₁₃ represents —H or —CH ₃ . X ₁ is represented by the general formula (2):
_{- (CH 2 CH 2 O)} a - (CH 2) b - (O) C -, indicates, X ₂ represents a -CN or -F. In the general formula (2), a is an integer of 0 to 3, b is an integer of 0 to 12, c is 0 or 1, and when a = 1 to 3, b = 0 and c = 0. Yes, when a = 0, b = 1 to 12, and c = 0 to 1. ).

  Specific examples of the polymerizable mesogenic compound (A) represented by the general formula (1) are listed in Table 1.

重合性メソゲン化合物（Ａ）はこれら例示化合物に限定されるものではない。

The polymerizable mesogenic compound (A) is not limited to these exemplified compounds.

  Examples of the polymerizable chiral agent (B) include LC756 manufactured by BASF.

  The blending amount of the polymerizable chiral agent (B) is preferably about 1 to 20 parts by weight, preferably 3 to 7 parts by weight based on 100 parts by weight of the total of the polymerizable mesogenic compound (A) and the polymerizable chiral agent (B). The part is more suitable. The helical twisting force (HTP) is controlled by the ratio of the polymerizable mesogenic compound (A) and the polymerizable chiral agent (B). By setting the ratio within the above range, the reflection band can be selected so that the reflection spectrum of the obtained cholesteric liquid crystal film can cover the long wavelength region.

  The liquid crystal mixture usually contains a photopolymerization initiator (C). Various kinds of photopolymerization initiators (C) can be used without particular limitation. Examples thereof include Irgacure 184, Irgacure 907, Irgacure 369, Irgacure 651 and the like manufactured by Ciba Specialty Chemicals. The blending amount of the photopolymerization initiator is preferably about 0.01 to 10 parts by weight with respect to 100 parts by weight of the total of the polymerizable mesogenic compound (A) and the polymerizable chiral agent (B), and 0.05 to 5 parts by weight. The part is more suitable.

  In order to widen the bandwidth of the resulting cholesteric liquid crystal film, the mixture can be mixed with an ultraviolet absorber to increase the ultraviolet exposure intensity difference in the thickness direction. Further, the same effect can be obtained by using a photoreaction initiator having a large molar extinction coefficient.

  The mixture can be used as a solution. Solvents used in preparing the solution are usually halogenated hydrocarbons such as chloroform, dichloromethane, dichloroethane, tetrachloroethane, trichloroethylene, tetrachloroethylene, chlorobenzene, phenols such as phenol and parachlorophenol, benzene, toluene, Aromatic hydrocarbons such as xylene, methoxybenzene, 1,2-dimethoxybenzene, others, acetone, methyl ethyl ketone, ethyl acetate, tert-butyl alcohol, glycerin, ethylene glycol, triethylene glycol, ethylene bricol monomethyl ether, diethylene glycol Dimethyl ether, ethyl cellosolve, butyl cellosolve, 2-pyrrolidone, N-methyl-2-pyrrolidone, pyridine, triethylamine, te Rahidorofuran, dimethylformamide, dimethylacetamide, dimethyl sulfoxide, can be used acetonitrile, butyronitrile, carbon disulfide, cyclopentanone, cyclohexanone and the like. The solvent to be used is not particularly limited, but methyl ethyl ketone, cyclohexanone, cyclopentanone and the like are preferable. Although the concentration of the solution depends on the solubility of the thermotropic liquid crystalline compound and the final film thickness of the cholesteric liquid crystal film, it cannot be generally stated, but it is usually preferably about 3 to 50% by weight.

  The production of the broadband cholesteric liquid crystal film of the present invention includes a step of applying the liquid crystal mixture to an alignment substrate and a step of polymerizing and curing the liquid crystal mixture by irradiating with ultraviolet rays.

  A conventionally known substrate can be used as the alignment substrate. For example, a thin film made of polyimide, polyvinyl alcohol or the like is formed on a substrate, and this is rubbed with a rayon cloth or the like, an obliquely deposited film, a polymer having a photocrosslinking group such as cinnamate or azobenzene, or polyimide with polarized ultraviolet rays A photo-alignment film, a stretched film, or the like that has been irradiated with is used. In addition, it can also be oriented by magnetic field, electric field orientation, and shear stress manipulation.

  The type of the base material is not particularly limited, but a material having a high transmittance is desirable in terms of a method of irradiating irradiation rays (ultraviolet rays) from the base material side. For example, the base material is required to have a transmittance of 10% or more, preferably 20% or more in the ultraviolet region of 200 nm to 400 nm, more preferably 300 nm to 400 nm. Specifically, it is preferably a plastic film having a transmittance for ultraviolet light having a wavelength of 365 nm of 10% or more, more preferably 20% or more. In addition, the transmittance | permeability is a value measured by U-4100 Spectrophotometer made from HITACHI.

  As the substrate, a film or glass plate made of plastic such as polyethylene terephthalate, triacetyl cellulose, norbornene resin, polyvinyl alcohol, polyimide, polyarylate, polycarbonate, polysulfone or polyethersulfone is used. Examples include triacetyl cellulose manufactured by Tochi Photo Film Co., Ltd., JSR ARTON, and Nippon Zeon ZEONEX.

  Moreover, the polymer film described in JP-A-2001-343529 (WO01 / 37007), for example, (A) a thermoplastic resin having a substituted and / or unsubstituted imide group in the side chain, and (B) a substitution in the side chain And / or a resin composition containing an unsubstituted phenyl and a thermoplastic resin having a nitrile group. A specific example is a film of a resin composition containing an alternating copolymer composed of isobutylene and N-methylmaleimide and an acrylonitrile / styrene copolymer. As the film, a film made of a mixed extruded product of the resin composition or the like can be used.

  The substrate may be used while being bonded to the cholesteric liquid crystal layer or may be peeled off. In the case where it is used while being bonded, a material having a sufficiently small phase difference value is used.

  When the substrate is used while being bonded, it is desirable that the substrate does not decompose, deteriorate or yellow even when irradiated with ultraviolet rays. For example, the intended purpose can be achieved by blending the aforementioned base material with a light stabilizer or the like. As the light stabilizer, Tinuvin 120 and 144 manufactured by Ciba Specialty Chemicals are preferably used. If the wavelength of 300 nm or less is cut from the exposure light, coloring, deterioration, and yellowing can be reduced.

  The coating thickness of the liquid crystal mixture (in the case of a solution, the coating thickness after solvent drying) is preferably about 1 to 20 μm. When the coating thickness is thinner than 1 μm, although the reflection bandwidth can be secured, the degree of polarization itself tends to decrease, which is not preferable. The coating thickness is preferably 2 μm or more, more preferably 3 μm or more. On the other hand, when the coating thickness is thicker than 20 μm, both the reflection bandwidth and the degree of polarization are not remarkably improved, and this is not preferable because it simply increases the cost. The coating thickness is more preferably 15 μm or less, and even more preferably 10 μm or less.

  As a method for applying the mixed solution to the alignment substrate, for example, a roll coating method, a gravure coating method, a spin coating method, a bar coating method, or the like can be employed. After application of the mixed solution, the solvent is removed and a liquid crystal layer is formed on the substrate. The conditions for removing the solvent are not particularly limited, and it is sufficient that the solvent can be generally removed and the liquid crystal layer does not flow or even flow down. Usually, the solvent is removed by drying at room temperature, drying in a drying furnace, heating on a hot plate, or the like.

  Next, the liquid crystal layer formed on the alignment substrate is brought into a liquid crystal state and cholesterically aligned. For example, heat treatment is performed so that the liquid crystal layer is in the liquid crystal temperature range. The heat treatment can be performed by the same method as the above drying method. The heat treatment temperature varies depending on the type of the liquid crystal material and the alignment substrate, and thus cannot be generally described, but is usually 60 to 300 ° C., preferably 70 to 200 ° C. The heat treatment time varies depending on the heat treatment temperature and the type of liquid crystal material and alignment substrate to be used, and cannot be generally specified, but is usually selected in the range of 10 seconds to 2 hours, preferably 20 seconds to 30 minutes.

  The step of applying to the alignment substrate and irradiating the liquid crystal mixture with ultraviolet rays includes the three steps (1) to (3).

In step (1), the alignment group is in contact with an oxygen-containing gas at an ultraviolet irradiation intensity of 20 to 200 mW / cm ² at a temperature of 20 ° C. or higher for 0.2 to 5 seconds. Irradiate UV from the material side. Thereby, the liquid crystal mixture is polymerized to form a polymer / oligomer having an average molecular weight of about 10,000 to 500,000, and the difference in reaction rate due to oxygen inhibition in the thickness direction of the alignment substrate side and the opposite side (oxygen interface side) A difference in the amount of radicals generated due to ultraviolet absorption of the liquid crystal composition occurs, and a layer in which the amount of polymer / oligomer generated is continuously distributed in the thickness direction is formed.

In the step (1), the temperature at the time of the first ultraviolet irradiation is a temperature of 20 ° C. or higher in order to polymerize and cure the liquid crystal mixture in a good alignment state. On the other hand, the upper limit of the temperature is not particularly limited, but is preferably 100 ° C. or lower. If the temperature is higher than 100 ° C., diffusion may occur during irradiation and management may be difficult. From these points, the temperature is preferably 20 ° C to 50 ° C. The first ultraviolet irradiation intensity is 20~200mW / cm ^2, preferably ^{25~200mW / cm 2, 40~150mW / cm} 2 is more preferable. If the ultraviolet irradiation intensity is lower than 20 mW / cm ² , the polymerization is not performed to the extent that a monomer distribution is formed in the thickness direction, and thus the band is not widened. On the other hand, if the ultraviolet irradiation intensity is higher than 200 mW / cm ² , the polymerization reaction rate becomes higher than the diffusion rate, so that it is not preferable because the band is not widened.

  In the step (1), the first ultraviolet irradiation time is 0.2 to 5 seconds, and preferably 0.3 to 3 seconds. More preferably, it is 0.5 to 1.5 seconds. When the time is shorter than 0.2 seconds, the polymerization is not performed to the extent that the monomer distribution is formed in the thickness direction, so that the band is not widened. On the other hand, when the time is longer than 5 seconds, the pitch change of the cholesteric liquid crystal layer is not a continuous change that becomes large to small from the alignment base material side to the oxygen interface side, but is not preferable. When the pitch is discontinuous, the coloring when viewed from an oblique angle becomes severe.

  The exposure environment in the ultraviolet irradiation is performed in a state where the liquid crystal mixture applied to the alignment substrate is in contact with a gas containing oxygen. The gas containing oxygen preferably contains 0.5% or more oxygen. Such an environment is not particularly limited as long as oxygen polymerization inhibition can be utilized, and can be performed in a general air atmosphere. Moreover, the oxygen concentration may be increased or decreased in view of the wavelength width intended for pitch control in the thickness direction and the speed required for polymerization. Although the necessary amount of the photopolymerization initiator (C) tends to increase in the air atmosphere, if Irgacure 184 and Irgacure 907 (both manufactured by Ciba Specialty Chemicals) are used, polymerization with the polymerizable mesogenic compound (A) is possible. The desired purpose can be achieved with an addition amount of about 1 to 5 parts by weight with respect to a total of 100 parts by weight of the chiral agent (B).

  In addition, in 1st ultraviolet irradiation, if the weight average molecular weight of the polymer / oligomer formed is too small, the diffusion rate becomes too high. Therefore, care should be taken not to make the polymer / oligomer concentration gradient uniform due to uncontrolled diffusion rates. In addition to forming a large change in the thickness direction of the cholesteric pitch length, it is necessary to maintain this. If the polymer / oligomer is too low in molecular weight, the formed gradient cannot be maintained, and the structure is lost due to molecular diffusion. In order to satisfy the conditions for managing the diffusion rate in terms of industrial conditions, a polymer / oligomer is formed in a weight average molecular weight range of about 10,000 to 500,000. The weight average molecular weight of the polymer / oligomer is preferably 100,000 to 300,000. The weight average molecular weight of the polymer / oligomer is a value measured by GPC method. The weight average molecular weight was calculated using polyethylene oxide as a standard sample. Main body: HLC-8120GPC manufactured by Tosoh, column: SuperAWM-H + SuperAWM-H + SuperAW3000 (6 mmφ × 15 cm, 45 cm in total) manufactured by Tosoh, column temperature: 40 ° C., eluent: 10 mM LiBr / NMP, flow rate: 0.4 ml / min, inlet pressure: 8.5 MPa, sample concentration: 0.1% NMP solution, detector: differential refractometer (RI).

  When the concentration distribution formed by the first ultraviolet irradiation in the step (1) is fixed as it is, only the reflection wavelength band of the same level as that of Patent Document 4 can be obtained.

  Therefore, in the step (2), the temperature rising rate is 2 ° C./second or higher until the temperature reaches 60 ° C. or higher in the state where the liquid crystal layer is in contact with the gas containing oxygen. Then, the ultraviolet rays are irradiated from the alignment substrate side for 10 seconds or more at a lower ultraviolet irradiation intensity than in the step (1). By the second ultraviolet irradiation in the step (2), the effective depth of polymerization inhibition by oxygen penetrating from the oxygen interface side can be made deeper than in the step (1), and the polymer / oligomer in the thickness direction in the step (1). The concentration gradient of the unpolymerized monomer component, which is formed in reverse because of the concentration gradient, can be made uniform. At the same time, by increasing the reaction only in the long pitch region on the alignment substrate side, the pitch increase on the alignment substrate side can be further increased.

  Since the increase in the molecular weight and the decrease in the diffusion rate of the liquid crystal composition layer are greatly different from those in the first ultraviolet irradiation in the step (1), the amount of radicals generated per unit time is reduced, and the progress rate of the polymerization is reduced. Further broadening is possible.

  In Patent Document 2, a time necessary for changing the temperature conditions of the first ultraviolet irradiation and the second ultraviolet irradiation and changing the composition ratio in the thickness direction is separately provided in a dark place. However, if an attempt is made to cover the entire visible light region by this method, the waiting time for mass transfer due to this temperature change needs to be about 120 minutes. On the other hand, in the manufacturing method of the present invention, a dark place is not particularly required. Furthermore, since the process can be completed in a short time within one minute, it is possible to produce a practical and highly efficient production rate.

  In the step (2), the second ultraviolet irradiation is performed while raising the temperature until a predetermined temperature is reached. In step (2), the starting temperature at the time of irradiation with the second ultraviolet ray is the same temperature as in step (1). That is, it is 20 ° C. or higher. When the starting temperature is lower than 20 ° C., the diffusion rate of the polymerizable mesogenic compound (a) is very slow, and it takes a long time to broaden the band. The ultimate temperature is set to a temperature higher than that in step (1) and 60 ° C. or higher. When the ultimate temperature is less than 60 ° C., the polymerizable mesogenic compound (a) does not sufficiently diffuse and does not sufficiently broadband. The upper limit of the reached temperature is not particularly limited, but 140 ° C. or less is preferable. Furthermore, the ultimate temperature is preferably 80 ° C to 120 ° C. When the ultimate temperature is higher than 140 ° C., the diffusion rate is too high and management is difficult.

At the time of the second ultraviolet irradiation, the temperature is rapidly increased to the ultimate temperature at a temperature increase rate of 2 ° C./second or more from the end of the first ultraviolet irradiation. When the rate of temperature rise is lower than 2 ° C./second, the polymerizable mesogenic compound (a) does not sufficiently diffuse and does not sufficiently widen the band. The temperature rising rate is preferably 2 to 20 ° C./second. After reaching the predetermined temperature, normally, the second ultraviolet irradiation can be performed while maintaining the temperature. Moreover, if it is the range of 140 degrees C or less, it can also be heated up gradually, after reaching predetermined | prescribed ultimate temperature. The second ultraviolet irradiation intensity is irradiated with an ultraviolet irradiation intensity lower than the first ultraviolet irradiation intensity. By making the illuminance lower than that at the time of the first ultraviolet irradiation, the oxygen inhibition depth becomes deeper than that at the time of the first ultraviolet irradiation, and the short wavelength band castle formed on the air interface side hardly changes. The long wavelength band on the side can be widened. In addition, it is preferable that ^2nd ultraviolet irradiation intensity | strength is 1-50 mW / cm < ² > in the range lower than 1st ultraviolet irradiation intensity | strength.

  The second ultraviolet irradiation time depends on the illuminance, but generally 10 seconds or longer is preferable. The second ultraviolet irradiation time is the total of the irradiation time until the temperature is rapidly raised to the reaching temperature and the irradiation time after reaching the reaching temperature. The ultraviolet irradiation time is preferably 120 seconds or shorter, more preferably 60 seconds or shorter from the viewpoint of working time. As described above, the broadening by the step (2) enables the widening as shown in the examples described later, and the viewing angle at which the color shift or color loss due to the blue shift of the oblique incident light beam becomes extremely large, and the coloring by the viewing angle is remarkable. It can be reduced.

  Next, in step (3), ultraviolet irradiation is performed in the absence of oxygen. By the third ultraviolet irradiation, the cholesteric reflection band expanded in the steps (1) and (2) is cured without deteriorating. Thereby, it fixes without degrading a pitch change structure.

  In the absence of oxygen, for example, an inert gas atmosphere can be used. The inert gas is not particularly limited as long as it does not affect the ultraviolet polymerization of the liquid crystal mixture. Examples of the inert gas include nitrogen, argon, helium, neon, xenon, and krypton. Among these, nitrogen is the most versatile and preferable. Moreover, it can also be made oxygen-free presence by bonding a transparent base material to a cholesteric liquid crystal layer.

  In the step (3), the ultraviolet irradiation may be performed from either the alignment substrate side or the applied liquid crystal mixture side.

The ultraviolet irradiation conditions are not particularly limited as long as the liquid crystal mixture is cured. Usually, it is preferable to irradiate for about 1 to 60 seconds with an irradiation intensity of about 40 to 300 mW / cm ² . Irradiation temperature is about 20-100 degreeC.

  As a result, the reliability is remarkably improved by improving the crosslinking density and increasing the molecular weight of the liquid crystal layer. In the present invention, ultraviolet irradiation from the alignment substrate surface side is performed in order to actively utilize oxygen inhibition by the first ultraviolet irradiation in the step (1) and the second ultraviolet irradiation in the step (2). For this reason, it is possible to form a large gradient in the reaction rate in the thickness direction, but problems such as low polymerization rate on the air interface side, insufficient film surface hardness / strength, or long-term reliability Problems may arise. For this reason, in the step (3), irradiation with the third ultraviolet ray is performed in an oxygen-free atmosphere to complete the polymerization of the remaining monomer, thereby enhancing the film quality. In this case, the reaction rate on the surface is not sufficiently improved under an air atmosphere (in the presence of oxygen), and it is difficult for the reaction rate to exceed 90%. Therefore, in order to obtain sufficient reliability, it is desired to perform ultraviolet irradiation in the absence of oxygen. The irradiation surface direction is not particularly limited. Although irradiation from the liquid crystal layer side is desirable, the surface reaction proceeds sufficiently even under irradiation from the substrate side in a nitrogen atmosphere.

  The cholesteric liquid crystal film thus obtained may be used without being peeled from the substrate, or may be peeled from the substrate.

  The broadband cholesteric liquid crystal film of the present invention is used as a circularly polarizing plate. A λ / 4 plate can be laminated on the circularly polarizing plate to form a linearly polarizing element. The cholesteric liquid crystal film which is a circularly polarizing plate is preferably laminated so that the pitch length is continuously narrowed with respect to the λ / 4 plate.

  The λ / 4 plate is not particularly limited, but is a general-purpose transparent resin film that generates a phase difference by stretching, such as polycarbonate, polyethylene terephthalate, polystyrene, polysulfone, polyvinyl alcohol, polymethyl methacrylate, or an ARTON film made by JSR. A norbornene-based resin film or the like is preferably used. Further, it is preferable to use a retardation plate that performs biaxial stretching and compensates for a change in retardation value due to an incident angle because the viewing angle characteristics can be improved. Further, a λ / 4 plate obtained by fixing a λ / 4 layer obtained by aligning liquid crystal, for example, other than the development of retardation due to stretching of the resin may be used. In this case, the thickness of the λ / 4 plate can be greatly reduced. The thickness of the λ / 4 wavelength plate is usually preferably from 0.5 to 200 μm, particularly preferably from 1 to 100 μm.

  A retardation plate that functions as a λ / 4 wavelength plate in a wide wavelength range such as a visible light region exhibits, for example, a retardation layer that functions as a λ / 4 wavelength plate and other retardation characteristics for light light having a wavelength of 550 nm. It can be obtained by a method of superposing a retardation layer, for example, a retardation layer functioning as a λ / 2 wavelength plate. Therefore, the retardation plate disposed between the polarizing plate and the brightness enhancement film may be composed of one or more retardation layers.

  An absorptive polarizer is bonded to the transmission axis of the linearly polarizing element so that the direction of the transmission axis is aligned.

  The polarizer is not particularly limited, and various types can be used. Examples of the polarizer include hydrophilic polymer films such as polyvinyl alcohol film, partially formalized polyvinyl alcohol film, and ethylene / vinyl acetate copolymer partially saponified film, and two colors such as iodine and dichroic dye. Examples thereof include polyene-based oriented films such as those obtained by adsorbing volatile substances and uniaxially stretched, polyvinyl alcohol dehydrated products and polyvinyl chloride dehydrochlorinated products. Among these, a polarizer composed of a polyvinyl alcohol film and a dichroic material such as iodine is preferable. The thickness of these polarizers is not particularly limited, but is generally about 5 to 80 μm.

  A polarizer obtained by dyeing a polyvinyl alcohol film with iodine and uniaxially stretching it can be produced, for example, by dyeing polyvinyl alcohol in an aqueous solution of iodine and stretching it 3 to 7 times the original length. If necessary, it can be immersed in an aqueous solution of boric acid or potassium iodide. Further, if necessary, the polyvinyl alcohol film may be immersed in water and washed before dyeing. In addition to washing the polyvinyl alcohol film surface with dirt and anti-blocking agents by washing the polyvinyl alcohol film with water, it also has the effect of preventing unevenness such as uneven coloring by swelling the polyvinyl alcohol film. is there. Stretching may be performed after dyeing with iodine, may be performed while dyeing, or may be dyed with iodine after stretching. The film can be stretched in an aqueous solution of boric acid or potassium iodide or in a water bath.

  The polarizer is usually used as a polarizing plate with a transparent protective film provided on one side or both sides. The transparent protective film is preferably excellent in transparency, mechanical strength, thermal stability, moisture shielding property, isotropy and the like. Examples of the transparent protective film include films made of transparent polymers such as polyester polymers such as polyethylene terephthalate and polyethylene naphthalate, cellulose polymers such as diacetyl cellulose and triacetyl cellulose, polycarbonate polymers, and acrylic polymers such as polymethyl methacrylate. Can be given. Styrene polymers such as polystyrene and acrylonitrile / styrene copolymers, polyethylene, polypropylene, polyolefins having a cyclic or norbornene structure, olefin polymers such as ethylene / propylene copolymers, vinyl chloride polymers, nylon and aromatic polyamides, etc. Examples thereof include films made of transparent polymers such as amide polymers. Furthermore, imide polymers, sulfone polymers, polyether sulfone polymers, polyether ether ketone polymers, polyphenylene sulfide polymers, vinyl alcohol polymers, vinylidene chloride polymers, vinyl butyral polymers, arylate polymers, polyoxymethylene polymers Examples thereof include a film made of a transparent polymer such as a polymer, an epoxy-based polymer, and a blend of the aforementioned polymers. In particular, those having a small optical birefringence are preferably used. From the viewpoint of the protective film of the polarizing plate, triacetyl cellulose, polycarbonate, acrylic polymer, cycloolefin resin, polyolefin having norbornene structure, and the like are preferable.

  Moreover, the polymer film described in JP-A-2001-343529 (WO01 / 37007), for example, (A) a thermoplastic resin having a substituted and / or unsubstituted imide group in the side chain, and (B) a substitution in the side chain And / or a resin composition containing an unsubstituted phenyl and a thermoplastic resin having a nitrile group. A specific example is a film of a resin composition containing an alternating copolymer composed of isobutylene and N-methylmaleimide and an acrylonitrile / styrene copolymer. As the film, a film made of a mixed extruded product of the resin composition or the like can be used.

  A transparent substrate that can be particularly preferably used in terms of polarization characteristics and durability is a triacetyl cellulose film whose surface is saponified with an alkali or the like. Although the thickness of a transparent protective film can be determined suitably, generally it is about 10-500 micrometers from points, such as workability | operativity, such as intensity | strength and handleability, and thin layer property. 20-300 micrometers is especially preferable, and 30-200 micrometers is more preferable.

  Moreover, it is preferable that a transparent protective film has as little color as possible. Therefore, Rth = [(nx + ny) / 2−nz] · d (where nx and ny are the main refractive index in the plane of the film, nz is the refractive index in the film thickness direction, and d is the film thickness). A protective film having a retardation value in the film thickness direction of −90 nm to +75 nm is preferably used. By using a film having a thickness direction retardation value (Rth) of −90 nm to +75 nm, the coloring (optical coloring) of the polarizing plate caused by the protective film can be almost eliminated. The thickness direction retardation value (Rth) is more preferably −80 nm to +60 nm, and particularly preferably −70 nm to +45 nm.

  The transparent protective film may be a transparent protective film made of the same polymer material on the front and back, or may be a transparent protective film made of a different polymer material or the like.

  The surface of the transparent protective film to which the polarizer is not adhered may be subjected to a hard coat layer, an antireflection treatment, an antisticking treatment, or a treatment for diffusion or antiglare.

  The hard coat treatment is applied for the purpose of preventing scratches on the surface of the polarizing plate. For example, a transparent protective film with a cured film excellent in hardness, sliding properties, etc. by an appropriate ultraviolet curable resin such as acrylic or silicone is used. It can be formed by a method of adding to the surface of the film. The antireflection treatment is performed for the purpose of preventing reflection of external light on the surface of the polarizing plate, and can be achieved by forming an antireflection film or the like according to the conventional art. Further, the anti-sticking treatment is performed for the purpose of preventing adhesion with an adjacent layer.

  The anti-glare treatment is applied for the purpose of preventing the outside light from being reflected on the surface of the polarizing plate and obstructing the visibility of the light transmitted through the polarizing plate. For example, the surface is roughened by a sandblasting method or an embossing method. It can be formed by imparting a fine concavo-convex structure to the surface of the transparent protective film by an appropriate method such as a blending method of transparent fine particles. The fine particles to be included in the formation of the surface fine concavo-convex structure are, for example, conductive materials made of silica, alumina, titania, zirconia, tin oxide, indium oxide, cadmium oxide, antimony oxide or the like having an average particle size of 0.5 to 50 μm. In some cases, transparent fine particles such as inorganic fine particles, organic fine particles composed of a crosslinked or uncrosslinked polymer, and the like are used. When forming a surface fine uneven structure, the amount of fine particles used is generally about 2 to 50 parts by weight, preferably 5 to 25 parts by weight, based on 100 parts by weight of the transparent resin forming the surface fine uneven structure. The antiglare layer may also serve as a diffusion layer (viewing angle expanding function or the like) for diffusing the light transmitted through the polarizing plate to expand the viewing angle.

  The antireflection layer, antisticking layer, diffusing layer, antiglare layer and the like can be provided on the transparent protective film itself, or can be provided separately from the transparent protective layer as an optical layer.

  The linearly polarizing element described above can be provided with an adhesive layer for adhering to other members such as a liquid crystal cell. The pressure-sensitive adhesive forming the pressure-sensitive adhesive layer is not particularly limited. For example, an acrylic polymer, silicone-based polymer, polyester, polyurethane, polyamide, polyether, fluorine-based or rubber-based polymer is appropriately selected. Can be used. In particular, those having excellent optical transparency such as an acrylic pressure-sensitive adhesive, exhibiting appropriate wettability, cohesiveness, and adhesive pressure-sensitive adhesive properties, and being excellent in weather resistance, heat resistance and the like can be preferably used.

  In addition to the above, in terms of prevention of foaming and peeling phenomena due to moisture absorption, deterioration of optical properties and liquid crystal cell warpage due to differences in thermal expansion, etc., as well as formability of liquid crystal display devices with high quality and excellent durability An adhesive layer having a low moisture absorption rate and excellent heat resistance is preferred.

  The adhesive layer is, for example, natural or synthetic resins, in particular, tackifier resins, fillers or pigments made of glass fibers, glass beads, metal powders, other inorganic powders, colorants, antioxidants, etc. It may contain an additive to be added to the adhesive layer. Moreover, the adhesion layer etc. which contain microparticles | fine-particles and show light diffusibility may be sufficient.

  The attachment of the adhesive layer can be performed by an appropriate method. For example, a pressure sensitive adhesive solution of about 10 to 40% by weight in which a base polymer or a composition thereof is dissolved or dispersed in a solvent composed of a suitable solvent alone or a mixture such as toluene and ethyl acetate is prepared. A method of attaching it directly on the polarizer by an appropriate development method such as a casting method or a coating method, or a method of forming an adhesive layer on a separator according to the above and transferring it onto an optical element, etc. Can be given. The pressure-sensitive adhesive layer can also be provided as an overlapping layer of different compositions or types in each layer. The thickness of the pressure-sensitive adhesive layer can be appropriately determined according to the purpose of use and adhesive force, and is generally 1 to 500 μm, preferably 5 to 200 μm, particularly preferably 10 to 100 μm.

  On the exposed surface of the adhesive layer, a separator is temporarily attached and covered for the purpose of preventing contamination until it is put to practical use. Thereby, it can prevent contacting an adhesion layer in the usual handling state. As the separator, except for the above thickness conditions, for example, a suitable thin leaf body such as a plastic film, rubber sheet, paper, cloth, non-woven fabric, net, foam sheet, metal foil, laminate thereof, and the like, silicone type or Appropriate conventional ones such as those coated with an appropriate release agent such as long-chain alkyl, fluorine-based, or molybdenum sulfide can be used.

  In addition, each layer such as the adhesive layer absorbs ultraviolet rays by a method such as a method of treating with a UV absorber such as a salicylic acid ester compound, a benzophenol compound, a benzotriazole compound, a cyanoacrylate compound, or a nickel complex compound. It may be a thing with a performance.

  The linearly polarizing element of the present invention can be preferably used for forming various devices such as a liquid crystal display device. The liquid crystal display device can be formed according to the conventional method. In other words, a liquid crystal display device is generally formed by appropriately assembling components such as a liquid crystal cell, an optical element, and an illumination system as necessary, and incorporating a drive circuit. However, the linearly polarizing element of the present invention is used. There is no limitation in particular except a point, and it can apply according to the former. As the liquid crystal cell, any type such as a TN type, an STN type, or a π type can be used.

  An appropriate liquid crystal display device such as a liquid crystal display device in which the linearly polarizing element is disposed on one side or both sides of a liquid crystal cell, or a backlight or a reflector used in an illumination system can be formed. In that case, the linearly polarizing element according to the present invention can be installed on one side or both sides of the liquid crystal cell. When linearly polarizing elements are provided on both sides, they may be the same or different. Further, when forming a liquid crystal display device, for example, a single layer or a suitable part such as a diffusion plate, an antiglare layer, an antireflection film, a protective plate, a prism array, a lens array sheet, a light diffusion plate, a backlight, Two or more layers can be arranged.

  The circularly polarizing plate (reflection polarizer) using the cholesteric liquid crystal film has a front phase difference (normal line) between at least two layers of the reflection polarizers (a) in which the wavelength bands of selective reflection of polarized light overlap each other. (Direction) is almost zero, and is used in a polarizing element system in which a phase difference layer (b) having a phase difference of λ / 8 or more with respect to incident light incident at an angle of 30 ° or more with respect to the normal direction is arranged. In addition, the cholesteric liquid crystal film may have either the maximum pitch or the minimum pitch of the helical twisted molecular structure on the phase difference layer (b) side, but from the viewpoint of the viewing angle (good viewing angle, small coloring), If the reflective polarizer (a) is expressed as (maximum pitch / minimum pitch), it is preferable that the reflective polarizer (a) is arranged as follows: maximum pitch / minimum pitch / phase difference layer (b) / maximum pitch / minimum pitch. Further, when combining λ / 4 plates, it is preferable to arrange the reflective polarizer (a) so that the minimum pitch side is the λ / 4 plate side.

  The polarizing element system, that is, the cholesteric liquid crystal laminate having a broadband selective reflection function has a circular polarization reflection / transmission function in the front direction, and can be used as a broadband circular polarizing plate in a liquid crystal display device. In this case, it can be used as a circularly polarizing plate by being arranged on the light source side of a circularly polarized liquid crystal cell, for example, a transmissive VA mode liquid crystal cell having a multi-domain.

  The retardation layer (b) has a phase difference of approximately zero in the front direction and a phase difference of λ / 8 or more with respect to incident light at an angle of 30 ° from the normal direction. Since the front phase difference is intended to maintain vertically incident polarized light, it is desirable that the front phase difference be λ / 10 or less.

  For incident light from an oblique direction, it is determined as appropriate depending on the angle at which it is totally reflected so as to be efficiently polarized and converted. For example, in order to achieve total reflection at an angle of about 60 ° from the normal line, the phase difference when measured at 60 ° may be determined to be about λ / 2. However, since the polarization state of the transmitted light from the reflective polarizer (a) is also changed by the C-plate-like birefringence of the reflective polarizer itself, the measured light at the angle of the C plate that is normally inserted is measured. The phase difference may be a value smaller than λ / 2. Since the phase difference of the C plate increases monotonously as the incident light is tilted, λ / 8 or more with respect to incident light at an angle of 30 ° as a guide for causing effective total reflection when tilted at an angle of 30 ° or more. Just have it.

  The material of the retardation layer (b) is not particularly limited as long as it has the above optical characteristics. For example, the planar alignment state of a cholesteric liquid crystal having a selective reflection wavelength other than the visible light region (380 nm to 780 nm), the homeotropic alignment state of a rod-like liquid crystal, or the columnar alignment or nematic alignment of a discotic liquid crystal , A negative uniaxial crystal oriented in the plane, a biaxially oriented polymer film, and the like.

  In the present invention, the C plate in which the planar alignment state of the cholesteric liquid crystal having a selective reflection wavelength other than the visible light region (380 nm to 780 nm) is fixed is not colored in the visible light region as the selective reflection wavelength of the cholesteric liquid crystal. Is desirable. Therefore, it is necessary that the selectively reflected light is not in the visible region. The selective reflection is uniquely determined by the cholesteric chiral pitch and the refractive index of the liquid crystal. Although the value of the center wavelength of selective reflection may be in the near-infrared region, it is more desirable to be in the ultraviolet region of 350 nm or less because it is affected by the optical rotation and a slightly complicated phenomenon occurs. The formation of the cholesteric liquid crystal layer is performed in the same manner as the formation of the cholesteric layer in the above-described reflective polarizer.

  The C plate in which the homeotropic alignment state is fixed in the present invention is a liquid crystalline thermoplastic resin or liquid crystal monomer exhibiting nematic liquid crystal properties at high temperatures, and an ionizing radiation such as an electron beam or ultraviolet ray, as necessary, and an alignment aid. A polymerizable liquid crystal polymerized by heat or a mixture thereof is used. The liquid crystallinity may be either lyotropic or thermotropic, but is preferably a thermotropic liquid crystal from the viewpoint of ease of control and ease of formation of a monodomain. Homeotropic alignment is obtained, for example, by coating the birefringent material on a film on which a vertical alignment film (long-chain alkylsilane or the like) is formed, and expressing and fixing a liquid crystal state.

  As a C plate using discotic liquid crystal, a discotic liquid crystal material having a negative uniaxial property such as a phthalocyanine or triphenylene compound having an in-plane molecular spread as a liquid crystal material, a nematic phase or a columnar phase is used. It is expressed and fixed. Examples of the negative uniaxial inorganic layered compound are detailed in JP-A-6-82777.

  C plate using biaxial orientation of polymer film is a method of biaxially stretching a polymer film having positive refractive index anisotropy in a balanced manner, a method of pressing a thermoplastic resin, and cutting out from a parallel oriented crystal. It is obtained by a method.

  The layers may be stacked, but it is desirable to stack the layers using an adhesive or a pressure-sensitive adhesive from the viewpoint of workability and light utilization efficiency. In that case, the adhesive or pressure-sensitive adhesive is transparent, has no absorption in the visible light region, and the refractive index is preferably as close as possible to the refractive index of each layer from the viewpoint of suppressing surface reflection. From this viewpoint, for example, an acrylic pressure-sensitive adhesive can be preferably used. Each layer is separately formed into a monodomain in the form of an alignment film, etc., and sequentially laminated by a method such as transfer to a translucent substrate, an alignment film or the like for alignment without providing an adhesive layer, etc. It is also possible to form each layer as appropriate and form each layer directly in sequence.

  In each layer and (viscous) adhesive layer, particles are added to adjust the degree of diffusion as necessary to give isotropic scattering, UV absorbers, antioxidants, leveling during film formation A surfactant or the like can be appropriately added for the purpose of imparting property.

  The polarizing element (cholesteric liquid crystal laminate) of the present invention has a circularly polarized light reflection / transmission function, but can be used as a linear polarization element that converts transmitted light into linearly polarized light by combining it with a λ / 4 plate. Examples of the λ / 4 plate are the same as those described above.

  The λ / 4 plate functions well only for a specific wavelength in a single layer made of a single material, but there is a problem that the function of the λ / 4 plate deteriorates for other wavelengths due to wavelength dispersion characteristics. Therefore, if the λ / 2 plate is laminated with a specified axial angle, it can be used as a broadband λ / 4 plate that functions in a practically acceptable range over the entire visible light range. In this case, each λ / 4 plate and λ / 2 plate may be made of the same material, or may be a combination of materials made of separate materials obtained in the same manner as the λ / 4 plate described above.

  For example, a λ / 4 plate (140 nm) is laminated on a broadband circularly polarizing plate, and the λ / 2 plate (270 nm) is arranged at 17.5 degrees with respect to this axial angle. In this case, the transmission polarization axis is 10 degrees with respect to the axis of the λ / 4 plate. Since the bonding angle varies depending on the phase difference value of each phase difference plate, the bonding angle is not limited to the above bonding angle.

  An absorptive polarizer is bonded to the transmission axis of the linearly polarizing element so that the direction of the transmission axis is aligned.

(Arrangement of diffuse reflector)
It is desirable to dispose a diffuse reflector on the lower side of the light guide plate as the light source (on the side opposite to the liquid crystal cell arrangement surface). The main component of the light beam reflected by the collimating film is an oblique incident component, and is regularly reflected by the collimating film and returned to the backlight direction. Here, when the reflector on the back side has high regular reflectivity, the reflection angle is preserved, and the light cannot be emitted in the front direction and becomes lost light. Accordingly, it is desirable to dispose a diffuse reflector in order to increase the scattering reflection component in the front direction without preserving the reflection angle of the reflected return beam.

(Distribution plate arrangement)
It is also desirable to install an appropriate diffusion plate between the collimating film and the backlight source in the present invention. This is because the light reuse efficiency is increased by scattering the incident and reflected light rays in the vicinity of the backlight light guide and scattering a part thereof in the vertical incident direction.

  The diffusion plate used can be obtained by a method of embedding fine particles having different refractive indexes in a resin, in addition to a surface irregularity shape. This diffusion plate may be sandwiched between the collimating film and the backlight, or may be bonded to the collimating film.

  When the liquid crystal cell having the collimated film attached thereto is disposed close to the backlight, there is a risk that Newton's ring may occur in the gap between the film surface and the backlight, but the light guide plate side surface of the collimated film in the present invention The occurrence of Newton rings can be suppressed by disposing a diffuser plate having surface irregularities on the surface. Moreover, you may form the layer which served as the uneven | corrugated structure and the light-diffusion structure in the surface itself of the collimating film in this invention.

(Arrangement of viewing angle expansion film)
The viewing angle expansion in the liquid crystal display device of the present invention diffuses a light beam with good display characteristics near the front surface obtained from the liquid crystal display device combined with a parallel light backlight, and is uniform within the entire viewing angle. It is obtained by obtaining good display characteristics.

  The viewing angle widening film used here is a diffusion plate that does not substantially have backscattering. The diffusion plate can be provided as a diffusion adhesive material. The location is on the viewing side of the liquid crystal display device, but it can be used either above or below the polarizing plate. However, it is desirable to provide a layer as close to the cell as possible, such as between the polarizing plate and the liquid crystal cell, in order to prevent the deterioration of the contrast due to the influence of the blur of the pixel or the like or the slight remaining backscattering. In this case, a film that does not substantially eliminate polarized light is desirable. For example, a fine particle dispersion type diffusion plate as disclosed in JP-A Nos. 2000-347006 and 2000-347007 is preferably used.

  When the viewing angle widening film is located outside the polarizing plate, the collimated light beam is transmitted from the liquid crystal layer to the polarizing plate, so that in the case of the TN liquid crystal cell, it is not necessary to use a viewing angle compensating retardation plate. In the case of an STN liquid crystal cell, it is only necessary to use a retardation film in which only the front characteristics are well compensated. In this case, since the viewing angle widening film has an air surface, it is possible to adopt a type based on a refraction effect due to the surface shape.

  On the other hand, when a viewing angle widening film is inserted between the polarizing plate and the liquid crystal layer, it becomes a diffused light at the stage where it passes through the polarizing plate. In the case of a TN liquid crystal, it is necessary to compensate for the viewing angle characteristics of the polarizer itself. In this case, it is necessary to insert a retardation plate for compensating the viewing angle characteristics of the polarizer between the polarizer and the viewing angle widening film. In the case of STN liquid crystal, it is necessary to insert a phase difference plate for compensating the viewing angle characteristics of the polarizer in addition to the front phase difference compensation of STN liquid crystal.

  In the case of a viewing angle widening film having a regular structure inside, such as a conventional microlens array film or hologram film, a microlens included in a black matrix of a liquid crystal display device or a conventional parallel light conversion system of a backlight Moire was likely to occur due to interference with a fine structure such as an array / prism array / louver / micromirror array. However, the collimated film in the present invention has no regular structure in the plane, and there is no regular modulation of the emitted light, so there is no need to consider compatibility with the viewing angle widening film and the arrangement order. Accordingly, the viewing angle widening film is not particularly limited as long as it does not cause interference / moire with the pixel black matrix of the liquid crystal display device, and the options are wide.

  In the present invention, it is a light scattering plate as described in JP-A-2000-347006 and JP-A-2000-347007, which has substantially no backscattering as a viewing angle widening film and does not cancel polarization. A haze of 80% to 90% is preferably used. In addition, a hologram sheet, a microprism array, a microlens array, or the like can be used as long as it does not form interference / moire with the pixel black matrix of the liquid crystal display device even if it has a regular structure inside.

  Note that the liquid crystal display device is manufactured by appropriately using various optical layers and the like according to a conventional method.

  EXAMPLES Hereinafter, although an Example and a comparative example are given and this invention is demonstrated, this invention is not limited to these Examples.

Example 1
Light polymerizable mesogenic compounds (polymerizable nematic liquid crystal monomer, Compound 20 of Table 1, the molar extinction ^{coefficient, 1dm 3 mol -1 cm -1 @} 365nm, 2100dm 3 mol -1 cm -1 @ 334nm, 36000dm 3 mol - ¹ cm ⁻¹ @ 314 nm (purity> 99% was used.) 94.8 parts by weight, polymerizable chiral agent (LC756 manufactured by BASF) 5.2 parts by weight and solvent (cyclopentanone) selective reflection center A coating solution (solid content 30% by weight) containing 3% by weight of a photopolymerization initiator (Ciba Specialty Chemicals Co., Ltd., Irgacure 907) based on the solid content of the solution adjusted to a wavelength of 550 nm. Was prepared. The coating solution was applied onto a stretched polyethylene terephthalate film (alignment substrate) using a wire bar so that the thickness after drying was 7 μm, and the solvent was dried at 100 ° C. for 2 minutes. The obtained film was irradiated with a first ultraviolet ray at 40 mW / cm ² for 1.2 seconds in an air atmosphere at 40 ° C. from the alignment substrate side. Subsequently, while raising the temperature to 90 ° C. at a temperature increase rate of 3 ° C./second (holding at 90 ° C. after arrival), the second ultraviolet irradiation is performed in an air atmosphere at 4 mW / cm ² for 60 seconds. went. Next, irradiation with the third ultraviolet ray from the alignment substrate side was performed at 60 mW / cm ² for 10 seconds in a nitrogen atmosphere at 50 ° C. to obtain a broadband cholesteric liquid crystal film having a selected wavelength of 425 to 900 nm. The reflection spectrum of the broadband cholesteric liquid crystal film is shown in FIG.

A negative biaxial retardation plate was transferred to the upper part of the obtained broadband cholesteric liquid crystal film (circularly polarizing reflector) using a translucent adhesive. This negative biaxial retardation plate was obtained by the following method. That is, cyclohexanone as a solvent was added to 93 parts by weight of a photopolymerizable nematic liquid crystal monomer (BASF, LC242), 7 parts by weight of a polymerizable chiral agent (LC756, BASF) so that the concentration was 30% by weight, and selective reflection was performed. After adjusting and blending so that the center wavelength becomes 350 nm, a coating solution in which 5% by weight of Irgacure 907 is added as a photopolymerization initiator to the above-mentioned solid content is prepared, and the above solution is wired to a stretched polyethylene terephthalate substrate. Using a bar, coating was performed so that the thickness after drying was 4 μm, and the solvent was dried at 100 ° C. for 2 minutes. Thereafter, the temperature was raised once to the isotropic transition temperature of the liquid crystal monomer, and then gradually cooled to form a layer having a uniform alignment state. The obtained layer was obtained by fixing the alignment state at 50 mW / cm ² for 5 seconds. When the phase difference of the negative biaxial retardation plate was measured, it was found that the phase difference was 120 nm when measured with an inclination of 2 nm and 30 ° in the front direction with respect to light having a wavelength of 550 nm. The phase difference was measured with KOBRA-21ADH manufactured by Oji Scientific Instruments.

  Furthermore, using the same translucent adhesive, the same circularly polarized light reflection plate as described above was transferred and laminated on the upper part to obtain a polarizing element. A λ / 4 plate (front retardation 140 nm) obtained by uniaxially stretching a polycarbonate film was bonded to the obtained polarizing element to obtain a linear polarizing element. A polarizing plate (polarized light integrated with polarizing plate) was obtained by laminating a polarizing plate (manufactured by Nitto Denko Corporation, TEG1465DU) to the linearly polarizing device so that the transmission axis directions coincide.

Example 2
The coating solution prepared in Example 1 was coated on a stretched polyethylene terephthalate film (alignment substrate) using a wire bar so that the thickness after drying was 7 μm, and the solvent was dried at 100 ° C. for 2 minutes. It was. The obtained film was irradiated with a first ultraviolet ray at 40 mW / cm ² for 1.2 seconds in an air atmosphere at 40 ° C. from the alignment substrate side. Subsequently, while the temperature was raised to 90 ° C. at a rate of 10 ° C./second (maintained at 90 ° C. after reaching), the second ultraviolet irradiation was performed at 4 mW / cm ² for 60 seconds in an air atmosphere. . Next, irradiation with the third ultraviolet ray from the alignment substrate side was performed at 60 mW / cm ² for 10 seconds in a nitrogen atmosphere at 50 ° C. to obtain a broadband cholesteric liquid crystal film having a selected wavelength of 430 to 900 nm. The reflection spectrum of the broadband cholesteric liquid crystal film is shown in FIG.

  A negative biaxial retardation plate similar to that in Example 1 was transferred to the upper portion of the obtained broadband cholesteric liquid crystal film (circularly polarizing reflector) using a translucent adhesive. Furthermore, using the same translucent adhesive, the same circularly polarized light reflection plate as described above was transferred and laminated on the upper part to obtain a polarizing element. A λ / 4 plate (front retardation 140 nm) obtained by uniaxially stretching a polycarbonate film was bonded to the obtained polarizing element to obtain a linear polarizing element. Further, a λ / 2 plate (front retardation 270 nm) obtained by uniaxially stretching a polycarbonate film was adhered on the λ / 4 plate to obtain a linearly polarizing element. A polarizing plate (polarized light integrated with polarizing plate) was obtained by laminating a polarizing plate (manufactured by Nitto Denko Corporation, TEG1465DU) to the linearly polarizing device so that the transmission axis directions coincide. These laminations were performed such that the angles of the stretching axis (slow axis) of the λ / 4 plate and λ / 2 plate and the stretching axis (absorption axis) of the polarizing plate were as shown in FIG.

Example 3
Light polymerizable mesogenic compounds (polymerizable nematic liquid crystal monomer, Compound 20 of Table 1, the molar extinction ^{coefficient, 1dm 3 mol -1 cm -1 @} 365nm, 2100dm 3 mol -1 cm -1 @ 334nm, 36000dm 3 mol - ¹ cm ⁻¹ @ 314 nm.) A solution in which 94.8 parts by weight, 5.2 parts by weight of a polymerizable chiral agent (LC756 manufactured by BASF) and a solvent (cyclopentanone) are adjusted and mixed so that the selective reflection center wavelength is 550 nm. In addition, a coating liquid (solid content: 30% by weight) was prepared by adding 0.3% by weight of a photopolymerization initiator (Ciba Specialty Chemicals, Irgacure 369) to the solid content. The coating solution was applied onto a stretched polyethylene terephthalate film (alignment substrate) using a wire bar so that the thickness after drying was 7 μm, and the solvent was dried at 100 ° C. for 2 minutes. The obtained film was irradiated with a first ultraviolet ray at 40 mW / cm ² for 1.2 seconds in an air atmosphere at 40 ° C. from the alignment substrate side. Subsequently, while the temperature was raised to 90 ° C. at a rate of 3 ° C./second (maintained at 90 ° C. after reaching), the second ultraviolet irradiation was performed at 4 mW / cm ² for 30 seconds in an air atmosphere. . Next, irradiation with the third ultraviolet ray from the alignment substrate side was performed at 60 mW / cm ² for 10 seconds in a nitrogen atmosphere at 50 ° C. to obtain a broadband cholesteric liquid crystal film having a selected wavelength of 420 to 925 nm. The reflection spectrum of the broadband cholesteric liquid crystal film is shown in FIG.

  A negative biaxial retardation plate similar to that in Example 1 was transferred to the upper portion of the obtained broadband cholesteric liquid crystal film (circularly polarizing reflector) using a translucent adhesive. Furthermore, using the same translucent adhesive, the same circularly polarized light reflection plate as described above was transferred and laminated on the upper part to obtain a polarizing element. A λ / 4 plate (front retardation 125 nm, Nz coefficient −1.0) obtained by biaxially stretching a polycarbonate film was bonded to the obtained polarizing element to obtain a linear polarizing element. A polarizing plate (polarized light integrated with polarizing plate) was obtained by laminating a polarizing plate (manufactured by Nitto Denko Corporation, TEG1465DU) to the linearly polarizing device so that the transmission axis directions coincide.

Example 4
Photopolymerizable mesogenic compound (polymerizable nematic liquid crystal monomer, compound 3 in Table 1 above, molar extinction coefficient is 0.1 dm ³ mol ⁻¹ cm ⁻¹ @ 365 nm, 2200 dm ³ mol ⁻¹ cm ⁻¹ @ 334 nm, 37000 dm ³ mol ^-1 cm ^-1 @ 314 nm) 94.8 parts by weight, 5.2 parts by weight of a polymerizable chiral agent (LC756 manufactured by BASF) and a solvent (cyclopentanone) are adjusted and mixed so that the selective reflection center wavelength is 550 nm. The coating solution (solid content 30 weight%) which added 3 weight% of photoinitiators (the Ciba Specialty Chemicals company make, Irgacure 907) with respect to the solid content was prepared. The coating solution was applied onto a stretched polyethylene terephthalate film (alignment substrate) using a wire bar so that the thickness after drying was 7 μm, and the solvent was dried at 100 ° C. for 2 minutes. The obtained film was irradiated with the first ultraviolet ray at 50 mW / cm ² for 2.2 seconds in an air atmosphere at 40 ° C. from the alignment substrate side. Subsequently, while raising the temperature to 90 ° C. at a rate of 3 ° C./second (holding at 90 ° C. after reaching), the second ultraviolet irradiation was performed in an air atmosphere at 4 mW / cm ² for 60 seconds. . Next, irradiation with the third ultraviolet ray from the alignment substrate side was performed at 60 mW / cm ² for 10 seconds in a nitrogen atmosphere at 50 ° C. to obtain a broadband cholesteric liquid crystal film having a selected wavelength of 455 to 930 nm. The reflection spectrum of the broadband cholesteric liquid crystal film is shown in FIG.

Comparative Example 1
The coating solution prepared in Example 1 was coated on a stretched polyethylene terephthalate film (alignment substrate) using a wire bar so that the thickness after drying was 5 μm, and the solvent was dried at 100 ° C. for 2 minutes. It was. The obtained film was irradiated with a first ultraviolet ray at 50 mW / cm ² for 10 seconds in an air atmosphere at 60 ° C. from the alignment substrate side. Subsequently, ultraviolet irradiation was performed at 60 mW / cm ² for 10 seconds from the alignment substrate side in a nitrogen atmosphere at 50 ° C. to obtain a broadband cholesteric liquid crystal film having a selection wavelength of 435 to 835 nm. The reflection spectrum of the broadband cholesteric liquid crystal film is shown in FIG.

  A negative biaxial retardation plate similar to that in Example 1 was transferred to the upper portion of the obtained broadband cholesteric liquid crystal film (circularly polarizing reflector) using a translucent adhesive. Furthermore, using the same translucent adhesive, the same circularly polarized light reflection plate as described above was transferred and laminated on the upper part to obtain a polarizing element. A λ / 4 plate (front retardation 140 nm) obtained by uniaxially stretching a polycarbonate film was bonded to the obtained polarizing element to obtain a linear polarizing element. A polarizing plate (polarized light integrated with polarizing plate) was obtained by laminating a polarizing plate (manufactured by Nitto Denko Corporation, TEG1465DU) to the linearly polarizing device so that the transmission axis directions coincide.

Comparative Example 2
The coating solution prepared in Example 1 was coated on a stretched polyethylene terephthalate film (alignment substrate) using a wire bar so that the thickness after drying was 7 μm, and the solvent was dried at 100 ° C. for 2 minutes. It was. The obtained film was irradiated with a first ultraviolet ray at 40 mW / cm ² for 1.2 seconds in an air atmosphere at 40 ° C. from the alignment substrate side. Subsequently, the temperature was raised to 90 ° C. at a rate of 3 ° C./second, and after reaching 90 ° C., the treatment was performed at 90 ° C. in an air atmosphere for 20 seconds. Next, ultraviolet irradiation was performed at 60 mW / cm ² for 10 seconds from the alignment substrate side in a nitrogen atmosphere at 50 ° C. to obtain a broadband cholesteric liquid crystal film having a selected wavelength of 415 to 710 nm. The reflection spectrum of the broadband cholesteric liquid crystal film is shown in FIG.

  A negative biaxial retardation plate similar to that in Example 1 was transferred to the upper portion of the obtained broadband cholesteric liquid crystal film (circularly polarizing reflector) using a translucent adhesive. Furthermore, using the same translucent adhesive, the same circularly polarized light reflection plate as described above was transferred and laminated on the upper part to obtain a polarizing element. A λ / 4 plate (front retardation 140 nm) obtained by uniaxially stretching a polycarbonate film was bonded to the obtained polarizing element to obtain a linear polarizing element. A polarizing plate (polarized light integrated with polarizing plate) was obtained by laminating a polarizing plate (manufactured by Nitto Denko Corporation, TEG1465DU) to the linearly polarizing device so that the transmission axis directions coincide.

Comparative Example 3
The coating solution prepared in Example 1 was coated on a stretched polyethylene terephthalate film (alignment substrate) using a wire bar so that the thickness after drying was 7 μm, and the solvent was dried at 100 ° C. for 2 minutes. It was. The obtained film was irradiated with a first ultraviolet ray at 40 mW / cm ² for 1.2 seconds in an air atmosphere at 40 ° C. from the alignment substrate side. Subsequently, while increasing the temperature to 90 ° C. at a temperature increase rate of 3 ° C./second (holding at 90 ° C. after reaching), ultraviolet irradiation is performed in an air atmosphere at 4 mW / cm ² for 60 seconds to select a wavelength. A broadband cholesteric liquid crystal film having a thickness of 425 to 900 nm was obtained. The reflection spectrum of the broadband cholesteric liquid crystal film is shown in FIG.

  A negative biaxial retardation plate similar to that in Example 1 was transferred to the upper portion of the obtained broadband cholesteric liquid crystal film (circularly polarizing reflector) using a translucent adhesive. Furthermore, using the same translucent adhesive, the same circularly polarized light reflection plate as described above was transferred and laminated on the upper part to obtain a polarizing element. A λ / 4 plate (front retardation 140 nm) obtained by uniaxially stretching a polycarbonate film was bonded to the obtained polarizing element to obtain a linear polarizing element. A polarizing plate (polarized light integrated with polarizing plate) was obtained by laminating a polarizing plate (manufactured by Nitto Denko Corporation, TEG1465DU) to the linearly polarizing device so that the transmission axis directions coincide.

(Liquid crystal display device)
The polarizing plate-integrated polarizing element obtained in each example was used as the lower plate of the TFT-LCD, while spherical silica particles (refractive in the acrylic adhesive material (thickness 25 μm, refractive index 1.47) were used on the upper plate side. A polarizing plate (manufactured by Nitto Denko Corporation, TEG1465DU) was laminated using a light scattering adhesive material (haze 80%) embedded with 20% by weight of a ratio 1.44 (diameter 4 μm).

  Further, a cold cathode tube having a diameter of about 3 mm was disposed on the side surface of the light guide having a fine prism structure on the lower surface, and the light source holder made of a silver-deposited polyethylene terephthalate film was covered. A silver-deposited polyethylene terephthalate film reflector was disposed on the lower surface of the light guide plate, and a polyethylene terephthalate film having a scattering layer made of styrene beads formed on the upper surface of the light guide plate. This was disposed below the polarizing plate integrated polarizing element as a light source.

  The case where the polarizing plate integrated polarizing element of Examples 1 and 3 and Comparative Examples 1 to 3 is used is FIG. 1, and the case where the polarizing plate integrated polarizing element of Example 2 is used is FIG. In Example 4, only the selective reflection wavelength band, bandwidth (Δλ), and pitch change were evaluated.

<Evaluation method>
The following evaluation was performed for the broadband cholesteric liquid crystal film (circularly polarizing reflector) and polarizing plate integrated polarizing element obtained above. The results are shown in Table 2. Table 2 also shows the conditions for each step of the examples and comparative examples.

(Selective reflection wavelength band and bandwidth (△ λ))
The reflection spectrum of the broadband cholesteric liquid crystal film was measured with a spectrophotometer (Otsuka Electronics Co., Ltd., Instant Multisystem MCPD2000), and the selective reflection wavelength band and the half-value width Δλ were determined. The half-value width Δλ is a reflection band at a reflectance that is half of the maximum reflectance.

(Pitch change)
The near-ultraviolet irradiation surface (1 μm lower layer from the ultraviolet irradiation surface) of the broadband cholesteric liquid crystal film, the air interface vicinity (1 μm lower layer from the air interface), and the intermediate pitch length were measured by cross-sectional TEM photographs.

(reliability)
When the broadband cholesteric liquid crystal film was put in a reliability test of 90% RH at 80 ° C. and 60 ° C. for 500 hours, it was evaluated whether or not precipitation of powdery material was observed on the surface.
○: No precipitate.
X: There is a precipitate.

(Front brightness)
It arrange | positioned on a dot printing type backlight so that the polarizing plate side of a polarizing plate integrated polarizing element may turn up, and evaluated with the luminance meter (the product made from TOPCON, BM-7).

(Oblique color change)
The oblique color change of the liquid crystal display device was evaluated according to the following criteria using a viewing angle measuring device EZ-CONTRAST manufactured by ELDIM.
Δxy = ((x ₀ −x ₁ ) ² + (y ₀ −y ₁ ) ² ) ^0.5
Front chromaticity (x ₀ , y ₀ ), chromaticity from diagonal ± 60 ° (x ₁ , y ₁ )
Good: Color change Δxy at a viewing angle of 60 ° is less than 0.04.
Defect: Color tone change Δxy at a viewing angle of 60 ° is 0.04 or more.

実施例では、長波長域を含む広帯域に選択反射波長を有するコレステリック液晶フィルムが得られている。当該コレステリック液晶フィルムは、信頼性が高くまた、これを円偏光板として用いた偏光素子は輝度向上特性にも優れている。また、当該偏光素子を用いた液晶表示装置は、諧調反転しない領域の表示情報を斜め方向に光拡散で振り分けたため、斜め方向からの色調変化や諧調反転が生じにくい視野角の広い液晶表示装置を得ることができる。

In the examples, a cholesteric liquid crystal film having a selective reflection wavelength in a wide band including a long wavelength region is obtained. The cholesteric liquid crystal film has high reliability, and a polarizing element using the cholesteric liquid crystal film as a circularly polarizing plate is excellent in luminance improvement characteristics. In addition, since the liquid crystal display device using the polarizing element distributes display information in a region where gradation is not inverted by light diffusion in an oblique direction, a liquid crystal display device having a wide viewing angle that hardly causes color change or gradation inversion from the oblique direction. Obtainable.

It is a conceptual diagram of the viewing angle expansion liquid crystal display device using the polarizing plate integrated polarizing element of Example 1, 3 and Comparative Examples 1-3. 6 is a conceptual diagram of a viewing angle widening liquid crystal display device using a polarizing plate integrated polarizing element of Example 2. FIG. FIG. 6 is a diagram illustrating the axis angle of each layer in the polarizing plate-integrated polarizing element of Example 2. 2 is a reflection spectrum of a cholesteric liquid crystal film produced in Example 1. 3 is a reflection spectrum of a cholesteric liquid crystal film produced in Example 2. 4 is a reflection spectrum of a cholesteric liquid crystal film produced in Example 3. 6 is a reflection spectrum of a cholesteric liquid crystal film produced in Example 4. 2 is a reflection spectrum of a cholesteric liquid crystal film produced in Comparative Example 1. 4 is a reflection spectrum of a cholesteric liquid crystal film produced in Comparative Example 2. 6 is a reflection spectrum of a cholesteric liquid crystal film produced in Comparative Example 3.

Claims (19)

A reflection bandwidth of 200 nm or more, including a step of applying a liquid crystal mixture containing a polymerizable mesogenic compound (A) and a polymerizable chiral agent (B) to an alignment substrate, and a step of polymerizing and curing the liquid crystal mixture by irradiating with ultraviolet rays. A method for producing a broadband cholesteric liquid crystal film having
The ultraviolet polymerization step includes
In a state where the liquid crystal mixture is in contact with a gas containing oxygen, UV irradiation is performed from the alignment substrate side at an ultraviolet irradiation intensity of 20 to 200 mW / cm ² at a temperature of 20 ° C. or higher for 0.2 to 5 seconds. Step (1) to perform,
Next, in a state where the liquid crystal layer is in contact with a gas containing oxygen, the temperature of the step (1) is higher than the step (1) and the temperature rise rate is 2 ° C./second or more until the temperature reaches 60 ° C. (2) a step of irradiating ultraviolet rays from the alignment substrate side for 10 seconds or more at a lower ultraviolet irradiation intensity than
Next, a method for producing a broadband cholesteric liquid crystal film, comprising the step (3) of irradiating ultraviolet rays in the absence of oxygen. 2. The method for producing a broadband cholesteric liquid crystal film according to claim 1, wherein the pitch length of the cholesteric liquid crystal film is changed so as to be continuously narrowed from the alignment substrate side. The broadband cholesteric liquid crystal according to claim 1 or 2, wherein the polymerizable mesogenic compound (A) has one polymerizable functional group, and the polymerizable chiral agent (B) has two or more polymerizable functional groups. A method for producing a film. The molar extinction coefficient of the polymerizable mesogenic compound (A) is
0.1 to 500 dm ³ mol ⁻¹ cm ⁻¹ @ 365 nm,
10-30000 dm ³ mol ⁻¹ cm ⁻¹ @ 334 nm, and
1000~100000dm ³ mol ^-1 cm ^-1 @ manufacturing method of broad band cholesteric liquid crystal film according to claim 1, characterized in that it is 314 nm. The polymerizable mesogenic compound (A) has the following general formula (1):

(In the formula, R _{1 to} R ₁₂ may be the same or different and represent —F, —H, —CH ₃ , —C ₂ H ₅ or —OCH ₃ , and R ₁₃ represents —H or —CH ₃ . X ₁ represents general formula (2): — (CH ₂ CH ₂ O) _a — (CH ₂ ) _b — (O) _C —, and X ₂ represents —CN or —F.
In the general formula (2), a is an integer of 0 to 3, b is an integer of 0 to 12, c is 0 or 1, and when a = 1 to 3, b = 0 and c = 0. Yes, when a = 0, b = 1 to 12, and c = 0 to 1.
The method for producing a broadband cholesteric liquid crystal film according to any one of claims 1 to 4, wherein the compound is represented by the formula: Between at least two reflective polarizers (a) in which the wavelength bands of selective reflection of polarized light overlap each other,
A retardation layer (b) having a front phase difference (normal direction) of substantially zero and a phase difference of λ / 8 or more with respect to incident light that is inclined by 30 ° or more with respect to the normal direction is disposed. A polarizing element,
A polarizing element, wherein the reflective polarizer (a) is a circularly polarizing plate using a broadband cholesteric liquid crystal film obtained by the production method according to claim 1 . The polarizing element according to claim 6 , wherein the selective reflection wavelengths of at least two layers of the reflective polarizer (a) overlap each other in a wavelength range of 550 nm ± 10 nm. A phase difference layer (b) in which the planar orientation of a cholesteric liquid crystal phase having a selective reflection wavelength region other than a visible light region is fixed;
A fixed liquid crystal in a homeotropic alignment state;
A fixed discotic liquid crystal nematic phase or columnar phase alignment state,
A biaxially oriented polymer film, or
The polarizing element according to claim 6 or 7 Symbol mounting, characterized in that the inorganic layered compound in the normal direction of the surface is obtained by orienting fixed so that the optical axes thereof with a negative uniaxial. A linearly polarizing element, wherein a λ / 4 plate is laminated on the polarizing element according to claim 6 , and linearly polarized light is obtained by transmission. The linearly polarizing element according to claim 9, which is obtained by laminating a cholesteric liquid crystal film, which is a circularly polarizing plate, on a λ / 4 plate so that the pitch length is continuously narrowed. 11. The linearly polarizing element according to claim 9 , wherein the λ / 4 plate is a retardation plate that is biaxially stretched to correct a phase difference of obliquely incident light rays to improve a viewing angle. The linearly polarizing element according to claim 9 or 10 , wherein the λ / 4 plate is a liquid crystal polymer type retardation plate obtained by applying and fixing nematic liquid crystal or smectic liquid crystal. When the λ / 4 plate has an in-plane main refractive index of nx and ny and a thickness direction main refractive index of nz, the Nz coefficient defined by the formula: (nx−nz) / (nx−ny) is The linearly polarizing element according to claim 9 , wherein the linearly polarizing element satisfies −0.5 to −2.5. A λ / 2 plate is further laminated on the λ / 4 plate of the linearly polarizing device according to claim 9 . 15. A linearly polarized light characterized in that an absorption polarizer in which the transmission axis of the linearly polarizing element according to claim 9 and the direction of the transmitting axis are aligned is laminated on the λ / 4 plate side of the linearly polarizing element. element. It has the polarizing element in any one of Claims 6-8 , or the linearly polarizing element in any one of Claims 9-15 in the surface side of the surface light source which has a reflection layer in the back side. Lighting device. A liquid crystal display device comprising a liquid crystal cell on a light emitting side of the illumination device according to claim 16 . 18. The viewing angle widening liquid crystal display device according to claim 17, wherein a viewing angle widening film for diffusing light on the viewing side that has passed through the liquid crystal cell is disposed on the viewing side with respect to the liquid crystal cell. 19. The viewing angle widening liquid crystal display device according to claim 18 , wherein a diffusion plate substantially free from backscattering and depolarization is used as the viewing angle widening film.

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