JP3912907B2 - Reflective liquid crystal element and liquid crystal display device using the same - Google Patents

Description

なお、屈折率は波長により数％の違いがある。
【００２３】

なお、光源には１００Ｗの高圧水銀ランプを用いた。ＵＶカット及びレンズ集光後の光源の分散スペクトルは図２の通りである（グラフは最大値で規格化してある）。また、光学系は、従来例と全く同じものを使用した。従って、光源を出た光は、フレネルレンズ２枚を通り、色分解ダイクロミラーによって、Ｒ、Ｇ、Ｂの３色に分解される。この際、実施例で用いた各色のダイクロミラーの波長カット特性は、図３の（Ａ）〜（Ｃ）の通りである。各色の液晶パネルには、図２の分光スペクトルと図３のカット特性を掛け合わせたものが入射する。
【００２４】
図３の（Ａ）〜（Ｃ）で解るように、本実施例では、カット波長が、それぞれ以下のように設定してある（“カット波長”＝通過率５０％の波長と定義）。
【００２５】
Ｂ：４８５（ｎｍ）
Ｇ：短波長側 ４８５（ｎｍ）、長波長側 ５７５（ｎｍ）
Ｒ：５９０（ｎｍ）
従来例でも述べたように、表示素子として、人間が目で見る場合の反射光の強度は、全反射光量を波長に対して、視感度補正を行って決定される。以上を踏まえて、様々な値のλ_T 、λ_ARのサンプルを作製し、反射率を測定した結果を以下に示す。
【００２６】
【表１】

【００２７】
【表２】

【００２８】
【表３】

上記結果から明らかなように、いずれの色においても、表面反射防止の最小波長λ_ARと界面反射防止の最小波長λ_T を一致させ、変化させた場合の最適値より、低反射となる条件が存在することがわかる。例えば、Ｂ色ではλ_AR＝λ_T の場合、４６７（ｎｍ）で０．２４％の最小値を得るが、λ_AR＝４８０（ｎｍ）、λ_T ＝４６７（ｎｍ）の組合わせの方が０．２３％と低い。Ｇ色もλ_AR＝λ_T ＝５４５（ｎｍ）に対し、λ_AR＝５５２（ｎｍ）、λ_T ＝５４５（ｎｍ）が最適である。また、Ｒ色ではλ_AR＝６２０（ｎｍ）、λ_T ＝６０５（ｎｍ）が最適となった。
【００２９】
図４には、Ｒ、Ｇ、Ｂの最適な反射分光スペクトルを表面、界面の両方（Ａ）（Ｂ）につき測定したものが示されている。ここでは、表面、界面とも、反射率最低の波長を中心軸とした時、分光スペクトルは、波長に対して非対称である。表面の反射防止では、長波長側で反射率が高くなり易く、界面では短波長側で反射率が高くなり易い。従って、ランプのスペクトルのように、ある特定波長を中心に広がりをもつ光に対して、反射防止を最適にするために、表面反射の最小波長と界面反射の最小波長とを故意にずらして設定しておくことが有効である。
【００３０】
なお、本実施例では、反射防止膜として、ＭｇＦ₂ ／ＺｒＯ₂ ／Ａｌ₂ Ｏ₃ 構成を用いたが、別の構成例としては、例えば、ＭｇＦ₂ の代わりに、Ｙ₂ Ｏ₃ あるいはＳｉＯ₂ を使用することができる。４層構成の場合、低反射率の波長帯域は３層構成より広くすることができるが、成膜コストは上昇する。また、４層構成の場合でも、界面反射の波長非対称性は残るので、本発明に係わる効果は発揮される。
【００３１】
また、本実施例では、ガラスに無アルカリガラス（ＮＨテクノグラスＮＡ−３５、コーニング１７３７など）を用いたが、低アルカリガラス、石英、擬似石英などを使用しても意義は変わらない。石英や擬似石英の場合、屈折率が１．４６程度であり、本実施例のガラスより空気に近いため、この値に適した表面反射防止膜、ＩＴＯ膜を検討する必要がある。更に、本実施例では、液晶材料として高分子分散型を使用したが、反射光がコントラストを低下させる恐れのあるものであれば、液晶材料の如何に拘わらず、本発明は有効である。
【００３２】
本実施例では、アクティブマトリクス基板として、半結晶シリコン上に画素電極およびアクティブマトリクス駆動するための駆動回路を形成した基板を使用したが、反射型である限り、パッシブなマトリクス基板であっても、多結晶ポリシリコンを利用した透明基板であっても、本発明の効果は有効に発揮される。
【００３３】
而して、本発明による反射型液晶素子を、Ｒ、Ｇ、Ｂの全ての色に使用し、従来例の光学系と同じ構成の、３板式投射型液晶表示装置を試作した。そして、本発明の液晶素子により、反射防止が、従来より有効に行うことが可能となったために、特に、液晶表示に際して、色のコントラストの向上に大きく寄与することができた。また、液晶表示素子としての膜構成は、従来より考えられる最も簡単な構成であり、成膜層数が少ないため、透明基板の歩留り向上、コスト低減が可能となり、その結果、液晶表示装置のコスト削減に大きく寄与した。
【００３４】
（実施例２）
本発明の第２の実施例では、構造的に、先述の実施例と同様の液晶素子が採用されるが、ダイクロミラーのカット波長の違いによる最適反射防止条件の違いを、明らかにしている（後述の実験結果を参照）。なお、表面反射防止の構造パラメータ、ＩＴＯ膜の物性定数、ガラスの物性値は、全て、先述の実施例と同じである。また、その評価に用いた光学系も、先述の実施例と同じである。因みに、使用した光源は１００Ｗの高圧水銀ランプである。
【００３５】
なお、ここでは、Ｇ色の液晶素子について、長波長側のカット波長を５７０、５７５、５８０（ｎｍ）と変化させた時の、最適反射防止について、実験を行っている。また、短波長側のカット波長は４８５（ｎｍ）である。
【００３６】
【表４】

【００３７】
【表５】

【００３８】
【表６】

以上の結果から解るように、ダイクロのカット波長に呼応して、表面反射防止、ＩＴＯの最適反射防止が変化する。実験した範囲では、カット波長のずれ量と最適波長のずれ量はほぼ等しい。また、何れの場合においても、本発明の主張である、表面反射防止膜の反射率最小波長が、ガラス／液晶界面の反射率最小波長より大きい値である、という点は実証されている。
【００３９】
上記のダイクロミラーのカット波長の最適値は、液晶表示装置に要求される明るさ、色度、コントラストなどにより変化するため、これらの仕様に基づき、最適な波長が選ばれるのは当然である。従って、表面反射防止及びガラス／液晶界面の反射防止も、上記の仕様に従って、最適化されなければならない。
【００４０】
なお、本実施例では、Ｇ色の長波長側のカット波長について、本発明の有効性を示したが、Ｇ色の短波長側、あるいは、Ｂ色、Ｒ色についても、ダイクロミラーのカット波長により、最適な反射防止が変わる。また、これらの如何なる組合せにおいても、本発明の効果が得られることも言うまでもない。
【００４１】
（実施例３）
本発明による第３の実施例では、光源として、２７０Ｗのメタルハライドランプを使用した場合についての本発明の有効性を示す。図５は、本実施例で使用したメタルハライドランプの分光スペクトルを示している。なお、この実施例で、ダイクロミラーのカット波長は、実施例１と全く同じものを用いた。その測定結果を以下に示す。
【００４２】
【表７】

【００４３】
【表８】

【００４４】
【表９】

ここでは、第１の実施例と同様に、Ｒ、Ｇ、Ｂの、全ての色において、λ_AR＝λ_T の場合より反射率の低い条件が存在することが解る。また、光源のスペクトルのピーク波長が、高圧水銀ランプとわずかに異なるため、最適な波長が高圧水銀の場合と多少、異なっている。なお、本実施例においても、表面反射防止の反射最小波長を、界面反射防止の最小波長より長波長側にずらすことで、両者を同じ波長にした場合と比較して、効果的な反射防止を行うことができる。
【００４５】
【発明の効果】
本発明は、以上詳述したようになり、以下のような効果が得られる。
１ 最も簡単な膜構成で、液晶素子の反射防止を、従来より最適化することが可能となった。
２ また、膜構成が簡単なため、成膜回数が少なく、欠陥の発生率や膜厚の規格はずれの確率が下がり、透明基板の製作歩留り向上につながった。
３ 液晶素子のコントラストが向上し、コストが低減されたために、この素子を用いて作製した投射型液晶表示装置の性能向上、コスト低減に寄与できる。
【図面の簡単な説明】
【図１】本発明の実施の形態を示す液晶素子の模式断面図である。
【図２】本発明に係わる光源分光スペクトルのグラフである。
【図３】（Ａ）〜（Ｃ）は、本発明による第１、第２実施例のダイクロカット特性のグラフである。
【図４】（Ａ）は本発明による第１実施例の表面反射スペクトル、（Ｂ）は本発明による第１実施例のガラス／液晶界面反射スペクトルである。
【図５】本発明による第３実施例の光源分光スペクトルである。
【図６】従来例の液晶素子の模式断面図である。
【図７】（Ａ）〜（Ｃ）は、従来例の光源分光スペクトル、表面反射スペクトル、界面反射スペクトルである。
【図８】従来例の光学性を示す構成図である。
【符号の説明】
１０１ 第２の基板（ガラス基板）
１０２ 第１の基板（アクティブマトリックス基板）
１０３ スペーサ
１０４ ポリマー
１０５ 液晶
１０６ 表面反射防止膜
１０７ 透明電極（ＩＴＯ）[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a liquid crystal element, in particular, a reflective liquid crystal element, and a liquid crystal display device using the same.
[0002]
[Prior art]
Liquid crystal elements are used mainly as display devices in many devices by taking advantage of many advantages such as thinness and light weight. In the large display device, the liquid crystal element is used and put into practical use in the form of a projection display that optically enlarges and projects the display image.
[0003]
In particular, in recent years, a reflective liquid crystal element has attracted attention as an element that realizes a high-luminance and high-definition display. In general, a projection display using a reflective liquid crystal element includes a light source 71, a condensing lens 72 that collects light from the light source 71, a Fresnel lens 73 that converts the collected light into parallel light, as shown in FIG. Fresnel lens 75 for condensing again, color separation mirror 76 for separating light source light into three primary colors of R, G, and B, field lens 77 for giving parallel light to the liquid crystal element, liquid crystal element 78, and reflection condensing It comprises a pinhole 79 for guiding to the projection optical system, a projection lens group 80, and a screen 81 for projecting an image.
[0004]
Note that a mirror 74 is disposed between the two Fresnel lenses 73 and 75 in order to fold the optical path. Further, in FIG. 8, for ease of understanding, an optical system of only one of the three primary colors is shown. However, actually, a plurality of color separation mirrors are arranged corresponding to the three primary colors, for example, Depending on the angle of the mirror, the light is guided in the direction of three different liquid crystal elements. Further, the reflected lights of R, G, and B are all projected through the same projection lens in a superimposed state.
[0005]
FIG. 6 is a diagram for explaining the structure of the liquid crystal element and the light input to and output from the liquid crystal element. In this liquid crystal element, a transparent substrate 1000 such as glass or quartz and an active matrix substrate 1002 having a reflective electrode 1001 are opposed substantially in parallel, and a liquid crystal substance 1004 is held in a region surrounded by a sealant 1003 therebetween. It is. A surface antireflection film 1005 is provided on the light incident side of the glass surface of the transparent substrate 1000 and is in contact with air, but a transparent electrode 1006 serving as a counter electrode is formed on the surface in contact with the liquid crystal substance.
[0006]
In the reflective liquid crystal element, in order to obtain a bright image, the reflected light 1008 reflected from the surface of the reflective electrode 1001 is extracted as much as possible with respect to the incident light 1007, and at the same time, the contrast ratio is increased as much as possible. It is necessary to make the surface reflected light 1009 and the glass / liquid crystal interface reflected light 1010 at the air / glass interface as small as possible.
[0007]
Therefore, normally, as shown in FIG. 7A, according to the light source light spectrum, for example, in the G color liquid crystal element, the surface reflection spectrum is changed to glass / The spectrum of the liquid crystal interface reflected light is as shown in FIG. That is, the minimum reflection wavelength of the surface antireflection coating and the glass / liquid crystal interface reflection is matched with the maximum peak wavelength of the spectrum. Actually, the human visual sensitivity characteristic peaks at 550 (nm) for G color and decreases on the low wavelength and high wavelength side. In particular, for R and B colors, the characteristic obtained by multiplying the light source light and the visual sensitivity characteristic ( Hereinafter, reflection prevention has been performed by a method of matching the minimum wavelength of reflection with the peak wavelength of light source light whose visibility has been corrected.
[0008]
[Problems to be solved by the invention]
However, in the above-described antireflection design, the reflection of the liquid crystal element cannot actually be minimized. In the conventional example, the total reflected light of the liquid crystal element as shown in FIG. 6 is the sum of the surface reflection spectral spectrum and the spectral spectrum of the glass / liquid crystal interface reflection. The reflected light mainly increases due to surface reflection, and the short wavelength side mainly increases due to interface reflection. Since the spectrum of the light source has a certain extent in the wavelength direction centering on the peak wavelength, in order to prevent reflection, it is necessary to secure a low reflection wavelength band according to this spread. Inadequate in terms.
[0009]
Therefore, both the surface reflection and the interface reflection can make a low reflection band wider by making the film structure of the liquid crystal element more complicated and multilayer, but it is disadvantageous in terms of cost and controllability. In particular, since it is common to use an ITO film as a transparent electrode on the interface side, in the single-layer film configuration, as shown in FIG. Inevitable. In addition, a low refractive index film such as MgF ₂ can be formed between ITO and glass. However, in order to obtain a desired antireflection performance, both MgF ₂ and ITO are about ± 1%. Therefore, there is a disadvantage that mass production control is required and mass productivity is extremely deteriorated.
[0010]
The present invention was made on the basis of the above circumstances, and the purpose thereof is to set the minimum wavelength of the reflectance of the surface antireflection film on which the reflectance on the long wavelength side is likely to rise to the longer wavelength side, In addition, the reflection type liquid crystal element that has a wide low reflection band with a reflection characteristic that matches the surface and interface by shifting the minimum reflection wavelength of the glass / liquid crystal interface, which tends to increase the reflectance on the short wavelength side, to a shorter wavelength. To provide.
[0011]
[Means for Solving the Problems]
For this reason, the present invention has a first substrate having a plurality of pixel electrodes and a transparent second substrate having a transparent electrode on the first surface, and the two substrates are arranged so that the respective electrodes face each other. In a reflective liquid crystal element in which a liquid crystal substance is opposed substantially in parallel, and an antireflection film composed of a plurality of films is formed on the second surface of the second substrate on the side opposite to the transparent electrode, The wavelength λ _{AR at} which the spectral reflectance of the antireflection film is minimized and the minimum wavelength λ _T of the spectral reflectance by the transparent electrode satisfy (λ _AR > λ _T ).
[0012]
In this case, as an embodiment of the present invention, the antireflection film is composed of three layers of magnesium fluoride (MgF ₂ ), zirconium oxide (ZrO ₂ ), and aluminum oxide (Al ₂ O ₃ ). The transparent electrode is formed of an ITO (Indium Tin Oxide) film having a refractive index of 1.65 to 1.95 in the visible light region. Preferably there is.
[0013]
In the present invention, the first substrate having a plurality of pixel electrodes and the transparent second substrate having a transparent electrode on the first surface, both substrates are liquid crystal so that the electrodes face each other. In a reflection type liquid crystal element in which an antireflection film composed of a plurality of films is formed on the second surface of the second substrate on the second surface of the second substrate on the opposite side of the transparent electrode with the substance interposed therebetween, The wavelength λ _{AR at} which the spectral reflectance of the antireflection film is minimized and the minimum wavelength λ _T of the spectral reflectance by the transparent electrode satisfy (λ _AR > λ _T +7 (nm)).
[0014]
Also in this case, the antireflection film comprises three layers of magnesium fluoride (MgF ₂ ), zirconium oxide (ZrO ₂ ), and aluminum oxide (Al ₂ O ₃ ), and the second substrate of the second substrate. It is preferable that the transparent electrode is an ITO (Indium Tin Oxide) film having a refractive index of 1.65 to 1.95 in the visible light region.
[0015]
Furthermore, in any case, it is a preferred embodiment that the liquid crystal substance is a polymer dispersed liquid crystal.
[0016]
In such a liquid crystal display device having a plurality of liquid crystal elements corresponding to each of the three primary colors, the reflection type liquid crystal element has a color separation and synthesis system for the three primary colors of R, G, and B. By using it for the R or B color, a liquid crystal display device having a preferred configuration can be obtained.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
As shown in FIG. 1, the basic configuration of the reflective liquid crystal element of the present invention is a first substrate (active matrix substrate) 102 having a plurality of pixel electrodes (not shown) and a transparent first surface. A transparent second substrate (glass substrate) 101 having an electrode 107, and a liquid crystal substance (both substrates 101, 102 injected into a region surrounded by a spacer 103 so that the electrodes face each other) Polymer-dispersed liquid crystal = liquid crystal 105 + polymer 104 (that is, the liquid crystal 105 is buried between the gaps of the polymer 104 constituting the network-like substance), facing each other substantially in parallel, and on the side opposite to the transparent electrode 107, the second An antireflection film 106 composed of a plurality of films is formed on the second surface of the substrate 101.
[0018]
In particular, according to the present invention, in this reflective liquid crystal element, the wavelength λ _{AR at} which the spectral reflectance of the antireflection film 106 is minimum and the minimum wavelength λ _T of the spectral reflectance by the transparent electrode 107 are (λ _AR > λ _T ) or (λ _AR > λ _T +7 (nm)). In this embodiment, the antireflection film 106 includes three layers of magnesium fluoride (MgF ₂ ), zirconium oxide (ZrO ₂ ), and aluminum oxide (Al ₂ O ₃ ). Further, the transparent electrode 107 is formed of only one layer on the second surface of the second substrate 101, and the transparent electrode 107 has a refractive index of 1.65 to 1.95 in the visible light region. It is an ITO (Indium Tin Oxide) film.
[0019]
In the present invention, such a reflective liquid crystal element has a color separation and synthesis system for the three primary colors R, G, and B, and has a plurality of liquid crystal elements corresponding to the three primary colors. Used for at least one, eg, R or B color.
[0020]
【Example】
Next, some examples of the liquid crystal element of the present invention will be presented regarding specific examples and performance.
[0021]
Example 1
In the embodiment of the present invention, the liquid crystal element having the configuration shown in FIG. 1 is used, and the structural parameters are as follows.
[0022]

The refractive index varies by several percent depending on the wavelength.
[0023]

A 100 W high-pressure mercury lamp was used as the light source. The dispersion spectrum of the light source after UV cut and lens condensing is as shown in FIG. 2 (the graph is normalized by the maximum value). The optical system used was exactly the same as the conventional example. Therefore, the light emitted from the light source passes through two Fresnel lenses and is separated into three colors R, G, and B by a color separation dichroic mirror. At this time, the wavelength cut characteristics of the dichroic mirrors of the respective colors used in the examples are as shown in FIGS. A product obtained by multiplying the spectral spectrum of FIG. 2 by the cut characteristics of FIG. 3 is incident on the liquid crystal panel of each color.
[0024]
As can be seen from FIGS. 3A to 3C, in this embodiment, the cut wavelengths are set as follows (defined as “cut wavelength” = wavelength with a pass rate of 50%).
[0025]
B: 485 (nm)
G: Short wavelength side 485 (nm), long wavelength side 575 (nm)
R: 590 (nm)
As described in the conventional example, as a display element, the intensity of reflected light when a human sees with eyes is determined by performing visibility correction on the total reflected light amount with respect to the wavelength. Based on the above, samples of various values of λ _T and λ _AR were prepared and the reflectance was measured.
[0026]
[Table 1]

[0027]
[Table 2]

[0028]
[Table 3]

As is clear from the above results, in any color, the minimum wavelength λ _AR for surface reflection prevention and the minimum wavelength λ _T for interface reflection prevention are made to coincide with each other, and there is a condition for lower reflection than the optimum value when changed. You can see that it exists. For example, in the B color, when λ _AR = λ _T , a minimum value of 0.24% is obtained at 467 (nm), but the combination of λ _AR = 480 (nm) and λ _T = 467 (nm) is better. As low as 0.23%. G color to be _{λ AR = λ T = 545 (} nm), λ AR = 552 (nm), λ T = 545 (nm) is optimal. For the R color, λ _AR = 620 (nm) and λ _T = 605 (nm) were optimum.
[0029]
FIG. 4 shows an optimum reflection spectrum of R, G, and B measured for both surface and interface (A) and (B). Here, both the surface and the interface have a spectral spectrum that is asymmetric with respect to the wavelength when the wavelength having the lowest reflectance is the central axis. In antireflection of the surface, the reflectance tends to be high on the long wavelength side, and the reflectance tends to be high on the short wavelength side at the interface. Therefore, the minimum wavelength for surface reflection and the minimum wavelength for interface reflection are deliberately shifted in order to optimize reflection prevention for light that spreads around a specific wavelength, such as the lamp spectrum. It is effective to keep it.
[0030]
In this embodiment, the MgF ₂ / ZrO ₂ / Al ₂ O ₃ structure is used as the antireflection film. However, as another structure example, for example, Y ₂ O ₃ or SiO ₂ instead of MgF ₂ is used. Can be used. In the case of the four-layer configuration, the wavelength band of low reflectance can be made wider than that of the three-layer configuration, but the film formation cost increases. Even in the case of the four-layer structure, the wavelength asymmetry of the interface reflection remains, so that the effect according to the present invention is exhibited.
[0031]
In this embodiment, non-alkali glass (NH techno glass NA-35, Corning 1737, etc.) is used as the glass, but the significance does not change even if low alkali glass, quartz, pseudo quartz, or the like is used. In the case of quartz or pseudo-quartz, the refractive index is about 1.46, which is closer to air than the glass of this embodiment, so it is necessary to consider a surface antireflection film and an ITO film suitable for this value. Further, in this embodiment, a polymer dispersion type is used as the liquid crystal material, but the present invention is effective regardless of the liquid crystal material as long as the reflected light may reduce the contrast.
[0032]
In this example, a substrate in which a pixel electrode and a drive circuit for driving an active matrix are formed on semi-crystalline silicon is used as an active matrix substrate, but a passive matrix substrate may be used as long as it is a reflection type. Even in the case of a transparent substrate using polycrystalline polysilicon, the effects of the present invention are effectively exhibited.
[0033]
Thus, the reflection type liquid crystal element according to the present invention was used for all colors of R, G, and B, and a three-plate projection type liquid crystal display device having the same configuration as that of the optical system of the conventional example was prototyped. Since the liquid crystal element of the present invention makes it possible to prevent reflection more effectively than in the past, it can greatly contribute to the improvement of color contrast, particularly in liquid crystal display. In addition, the film structure as a liquid crystal display element is the simplest conceivable structure conventionally, and since the number of film formation layers is small, the yield of transparent substrates can be improved and the cost can be reduced. Significantly contributed to the reduction.
[0034]
(Example 2)
In the second embodiment of the present invention, the same liquid crystal element as that of the previous embodiment is structurally adopted, but the difference in the optimum antireflection condition due to the difference in the cut wavelength of the dichroic mirror is clarified ( (See experimental results below). The structural parameters for preventing surface reflection, the physical constants of the ITO film, and the physical properties of the glass are all the same as in the previous examples. Also, the optical system used for the evaluation is the same as that of the above-described embodiment. Incidentally, the light source used is a 100 W high pressure mercury lamp.
[0035]
In this case, an experiment is performed for optimum antireflection when the cut wavelength on the long wavelength side is changed to 570, 575, and 580 (nm) for the G liquid crystal element. The cut wavelength on the short wavelength side is 485 (nm).
[0036]
[Table 4]

[0037]
[Table 5]

[0038]
[Table 6]

As understood from the above results, the surface reflection prevention and the optimum reflection prevention of ITO change in response to the dichroic cut wavelength. In the experimental range, the shift amount of the cut wavelength and the shift amount of the optimum wavelength are almost equal. Moreover, in any case, it is proved that the minimum reflectance wavelength of the surface antireflection film, which is the assertion of the present invention, is larger than the minimum reflectance wavelength of the glass / liquid crystal interface.
[0039]
Since the optimum value of the cut wavelength of the dichroic mirror varies depending on the brightness, chromaticity, contrast, etc. required for the liquid crystal display device, the optimum wavelength is naturally selected based on these specifications. Therefore, surface antireflection and glass / liquid crystal interface antireflection should also be optimized according to the above specifications.
[0040]
In the present embodiment, the effectiveness of the present invention is shown for the cut wavelength on the long wavelength side of G color, but the cut wavelength of the dichroic mirror is also used for the short wavelength side of G color, or B color and R color. Changes the optimal antireflection. In addition, it goes without saying that the effect of the present invention can be obtained by any combination thereof.
[0041]
(Example 3)
The third embodiment of the present invention shows the effectiveness of the present invention when a 270 W metal halide lamp is used as the light source. FIG. 5 shows the spectrum of the metal halide lamp used in this example. In this example, the cut wavelength of the dichroic mirror was exactly the same as in Example 1. The measurement results are shown below.
[0042]
[Table 7]

[0043]
[Table 8]

[0044]
[Table 9]

Here, as in the first embodiment, it can be seen that there are conditions with lower reflectivity than in the case of λ _AR = λ _T for all the colors R, G, and B. Moreover, since the peak wavelength of the spectrum of the light source is slightly different from that of the high-pressure mercury lamp, the optimum wavelength is somewhat different from that of high-pressure mercury. Also in this example, by shifting the reflection minimum wavelength for surface reflection prevention to the longer wavelength side than the minimum wavelength for interface reflection prevention, effective reflection prevention can be achieved compared to the case where both are set to the same wavelength. It can be carried out.
[0045]
【The invention's effect】
The present invention has been described in detail above, and the following effects can be obtained.
1. With the simplest film configuration, it has become possible to optimize the antireflection of liquid crystal elements.
2 Further, since the film structure is simple, the number of film formations is small, the probability of occurrence of defects and the probability of deviation from the standard of the film thickness are reduced, and the production yield of transparent substrates is improved.
3 Since the contrast of the liquid crystal element is improved and the cost is reduced, it is possible to contribute to the improvement in performance and cost of the projection type liquid crystal display device manufactured using this element.
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view of a liquid crystal element showing an embodiment of the present invention.
FIG. 2 is a graph of a light source spectrum according to the present invention.
FIGS. 3A to 3C are graphs of dichroic cut characteristics of the first and second embodiments according to the present invention. FIGS.
4A is a surface reflection spectrum of the first embodiment according to the present invention, and FIG. 4B is a glass / liquid crystal interface reflection spectrum of the first embodiment according to the present invention.
FIG. 5 is a light source spectrum of the third embodiment according to the present invention.
FIG. 6 is a schematic cross-sectional view of a conventional liquid crystal element.
7A to 7C are a light source spectrum, a surface reflection spectrum, and an interface reflection spectrum of a conventional example.
FIG. 8 is a configuration diagram showing optical properties of a conventional example.
[Explanation of symbols]
101 Second substrate (glass substrate)
102 First substrate (active matrix substrate)
103 spacer 104 polymer 105 liquid crystal 106 surface antireflection film 107 transparent electrode (ITO)

Claims (8)

It has a first substrate having a plurality of pixel electrodes and a transparent second substrate having a transparent electrode on the first surface, and both substrates are substantially parallel with a liquid crystal substance sandwiched so that the electrodes face each other. In a reflection type liquid crystal element in which an antireflection film comprising a plurality of films is formed on the second surface of the second substrate on the opposite side to the transparent electrode,
The wavelength λ _{AR at} which the spectral reflectance of the antireflection film is minimized and the minimum wavelength λ _T of the spectral reflectance by the transparent electrode are λ _AR > λ _T
A reflective liquid crystal element characterized by satisfying _2. The reflective liquid crystal element according to claim 1, wherein the antireflection film comprises three layers of magnesium fluoride (MgF ₂ ), zirconium oxide (ZrO ₂ ), and aluminum oxide (Al ₂ O ₃ ). The transparent electrode is formed of only one layer on the second surface of the second substrate, and the transparent electrode is made of ITO (Indium Tin Oxide) having a refractive index of 1.65 to 1.95 in the visible light region. The reflective liquid crystal element according to claim 1, wherein the reflective liquid crystal element is a film. It has a first substrate having a plurality of pixel electrodes and a transparent second substrate having a transparent electrode on the first surface, and both substrates are substantially parallel with a liquid crystal substance sandwiched so that the electrodes face each other. In a reflection type liquid crystal element in which an antireflection film comprising a plurality of films is formed on the second surface of the second substrate on the opposite side to the transparent electrode,
The wavelength λ _{AR at} which the spectral reflectance of the antireflection film is minimized and the minimum wavelength λ _T of the spectral reflectance by the transparent electrode are λ _AR > λ _T +7 (nm)
A reflective liquid crystal element characterized by satisfying 5. The reflection type liquid crystal element according to claim 4, wherein the antireflection film comprises three layers of magnesium fluoride (MgF ₂ ), zirconium oxide (ZrO ₂ ), and aluminum oxide (Al ₂ O ₃ ). The transparent electrode is formed of only one layer on the second surface of the second substrate, and the transparent electrode is made of ITO (Indium Tin Oxide) having a refractive index of 1.65 to 1.95 in the visible light region. 6. The reflective liquid crystal element according to claim 4, wherein the reflective liquid crystal element is a film. The reflective liquid crystal element according to claim 1, wherein the liquid crystal substance is a polymer-dispersed liquid crystal. In a liquid crystal display device having a plurality of liquid crystal elements corresponding to each of the three primary colors, the liquid crystal display device having a color separation / combination system for the three primary colors of R, G, and B, wherein at least one of the liquid crystal elements is defined in claims 1 to 7. A liquid crystal display device characterized by being a reflective liquid crystal element.

Images