The present invention relates to an active matrix substrate, a display panel, a display device, and a method for manufacturing the active matrix substrate, and more particularly relates to an active matrix substrate comprising a transistor element, particularly a thin film transistor (TFT) element, a display panel, a display device, and a method for manufacturing an active matrix substrate.
In recent years, flat panel display (FPD) devices represented by liquid-crystal display (LCD) devices and organic EL (Electroluminescent) display devices have been developed intensively, because these devices are capable of achieving reduced consumption power, low drive voltage, and space savings.
In an FPD device, a driving method for a liquid-crystal display device and an organic EL display device is roughly classified into two methods, that is, a static driving method and a dynamic driving method. An active matrix driving method classified as the dynamic driving method has attracted attention because it can reduce crosstalk between pixels and reproduce images more clearly.
At the time of realizing the active matrix driving method, a circuit substrate that is a so-called array substrate comprising one or more switching elements and capacitive elements for each pixel is generally used. Such a substrate is called active matrix substrate in this specification.
For example, in a case of a liquid-crystal display device, a liquid crystal element is provided between an active matrix substrate and an opposing substrate. Light generated by a light source in the device is viewed through the active matrix substrate, the liquid crystal element, and the opposing substrate. At this time, a voltage is applied as appropriate to the liquid crystal element for controlling a molecular arrangement thereof, so that a color tone and a gradation of images are represented.
Further, in a case of an organic EL display device, an organic-light emitting diode is provided on one main surface side of the active matrix substrate for each pixel. Light from the organic-light emitting diode is viewed through the active matrix substrate (a bottom emission type) or not through the active matrix substrate (a top emission type). At this time, by controlling the amount of current flowing in the organic-light emitting diode, the color tone and the gradation of images are represented.
Due to the above configurations, the active matrix substrate is an important factor for determining the thickness of a panel in the FPD such as a liquid-crystal display device or an organic EL display device. A transistor element, particularly a thin film element such as a TFT element, is generally used for a switching element of the active matrix substrate in view of slimming down of a panel part.
Because electrode materials, semiconductor materials, and insulating films have been developed, a transparent TFT can be formed (see, for example, Nonpatent literature 1 mentioned below).
Nonpatent Literature
Nonpatent literature 1: Toshio KAMIYA, et al., “Designing of amorphous oxide semiconductors and room-temperature fabrication of high-performance flexible thin-film transistors”, Transactions of the 19th Advanced Technology Award, [online], [searched on Apr., 9, 2008], Internet <URL:http://www.fbi-award.jp/sentan/jusyou/2005/toko_canon.pdf>
An aperture ratio of an active matrix substrate is one of factors for determining a performance of a liquid-crystal display device and an organic EL display device. This aperture ratio is an important factor for realizing higher density, higher contrast ratio, and higher brightness. As the aperture ratio is increased, high integration, high contrast ratio, and high brightness can be realized.
However, while a transistor element in the active matrix substrate can be made transparent by the conventional techniques described above, wiring parts cannot be made transparent by these conventional techniques.
A large cross-sectional area is required for wirings to reduce the consumption power and drive voltage of a liquid-crystal display device and an organic EL display device. Therefore, lack of transparency of the wirings restricts an improvement in the aperture ratio of conventional active matrix substrates.
Therefore, the present invention has been achieved in view of the above problems, and an object of the invention is to provide an active matrix substrate capable of improving an aperture ratio, a display panel, a display device, and a method for manufacturing an active matrix substrate.
For achieving the above object, the present invention provides the following:
[1] An active matrix substrate having a plurality of transistor elements, the active matrix substrate comprising:
a substrate that can transmit visible light;
a wiring that is formed on the substrate and can transmit visible light;
a semiconductor layer that overlaps at least a part of the wiring in a thickness direction of the substrate and can transmit visible light; and
an insulating film that covers at least a part of the wiring and of the semiconductor layer and can transmit visible light.
[2] The active matrix substrate according to above [1], wherein the wiring comprises a main wiring and a sub-wiring that is branched from the main wiring and connects the main wiring to the transistor element.
[3] The active matrix substrate according to above [1] or [2], wherein the wiring is made of an inorganic oxide conductive material.
[4] The active matrix substrate according to any one of above [1] to [3], wherein the semiconductor layer is made of an inorganic oxide semiconductor material.
[5] The active matrix substrate according to any one of above [1] to [4], wherein
the wiring is made of a conductive material made of zinc tin oxide or indium containing oxide, and
the semiconductor layer is made of a semiconductor material that has a lower carrier density than that of the wiring and is made of zinc tin oxide or indium containing oxide.
[6] The active matrix substrate according to any one of above [1] to [5], wherein a part of the wiring functions as an electrode in the transistor element.
[7] The active matrix substrate according to any one of above [1] to [6], wherein a part of the wiring functions as a gate electrode, a source electrode, and a drain electrode in the transistor element, and a part of the insulating film functions as a gate insulating film in the transistor element.
[8] The active matrix substrate according to any one of above [1] to [7], comprising a first transistor, a second transistor, and a capacitor, wherein
the wiring constitutes at least a part of one or more scanning lines, at least a part of one or more data lines, and at least a part of one or more drive lines,
a control terminal of the first transistor is connected to the scanning line and an input terminal thereof is connected to the data line,
a control terminal of the second transistor is connected to an output terminal of the first transistor and an input terminal thereof is connected to the drive line, and
one electrode of the capacitor is connected to the drive line and the other terminal of the capacitor is connected to the control terminal of the second transistor.
[9] The active matrix substrate according to any one of above [1] to [7], comprising a first transistor and a capacitor, wherein
the wiring constitutes at least a part of one or more scanning lines, at least a part of one or more data lines, and at least a part of one or more capacitance lines,
a control terminal of the first transistor is connected to the scanning line and an input terminal thereof is connected to the data line, and
one terminal of the capacitor is connected to an output terminal of the transistor.
[10] A display panel comprising:
the active matrix substrate according to any one of above [1] to [8];
a first electrode that is formed on the active matrix substrate and can transmit visible light;
an organic film formed on the first electrode; and
a second electrode formed on the organic film.
[11] The display panel according to above [10], wherein the second electrode can transmit visible light.
[12] The display panel according to above [11], comprising an auxiliary electrode that is electrically connected to the second electrode.
[13] The display panel according to above [12], wherein the auxiliary electrode can transmit visible light.
[14] The display panel according to any one of above [10] to [13], comprising a filter film that is formed on one or both of an upper layer and a lower layer with respect to the organic film.
[15] A display panel comprising:
the active matrix substrate according to any one of above [1] to [7] and [9];
an opposing substrate that can transmit visible light; and
a liquid crystal element that comprises a liquid crystal layer, two alignment films that sandwich the liquid crystal layer, and a pixel electrode and a common electrode that sandwich a laminated body comprising the liquid crystal layer and the two alignment films, wherein
the pixel electrode and the common electrode can transmit visible light,
the pixel electrode is electrically connected to the wiring in the active matrix substrate, and
the liquid crystal element is sandwiched between the active matrix substrate and the opposing substrate.
[16] The display panel according to above [15], comprising two polarizing plates that sandwich a laminated body that comprises the active matrix substrate, the liquid crystal element, and the opposing substrate.
[17] The display panel according to above [15] or [16], comprising:
a light shielding film formed on the common electrode; and
a filter film that is formed at least on the common electrode and transmits a wavelength of a predetermined band.
[18] A display device comprising the display panel according to any one of above [10] to [17].
[19] A method for manufacturing an active matrix substrate comprising:
forming a first wiring a part of which comprises an electrode that forms a transistor element, and that can transmit visible light on a substrate that can transmit visible light;
forming a first insulating film that covers at least a part of the first wiring, a part of which comprises an insulating film that forms the transistor element, and that can transmit visible light on the substrate;
forming a second wiring a part of which comprises an electrode that forms the transistor element and that can transmit visible light on the first insulating film;
forming a semiconductor layer that covers at least a part of the second wiring and can transmit visible light on the first insulating film; and
forming a second insulating film that covers at least a part of the semiconductor layer and of the second wiring and can transmit visible light on the first insulating film.
[20] The method for manufacturing an active matrix substrate according to above [19], wherein the second wiring is formed by using an inorganic oxide conductive material.
[21] The method for manufacturing an active matrix substrate according to above [19] or [20], wherein the semiconductor layer is formed by using an inorganic oxide semiconductor material.
[22] The method for manufacturing an active matrix substrate according to any one of above [19] to [21], wherein
the second wiring is formed by using a conductive material made of zinc tin oxide or indium containing oxide, and
the semiconductor layer is formed by using a semiconductor material made of zinc tin oxide or indium containing oxide that can realize a lower carrier density than that of the wiring.
[23] The method for manufacturing an active matrix substrate according to any one of above [19] to [22], wherein at the step of forming the semiconductor layer, a semiconductor film that covers the second wiring is formed on the first insulating film and etched such that the second wiring is not exposed, so that the semiconductor layer is formed.
[24] The method for manufacturing an active matrix substrate according to any one of above [19] to [23], wherein at at least one of steps of forming the first wiring, the first insulating film forming step, the second wiring forming step, the semiconductor layer forming step, and the second insulating film forming step, the first wiring, the first insulating film, the second wiring, the semiconductor layer, or the second insulating film is formed by printing method or ink jet printing method.
According to the present invention, the wiring in the active matrix substrate is transparent with respect to visible light, and thus the aperture ratio of the active matrix substrate can be remarkably improved. Because of the same reason, according to the present invention, the active matrix substrate with a remarkably improved aperture ratio can be manufactured. By using such an active matrix substrate according to the present invention, the display panel and the display device with a remarkably improved aperture ratio can be realized.
Exemplary embodiments of the present invention will be explained below in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments. Further, in the following explanations, the drawings merely schematically depict the shape, size, and positional relationships to an extent that the content of the present invention can be understood. Therefore, the present invention is not limited only to the shape, size, and positional relationships exemplified in the respective drawings. In addition, for simplifying configurations, a part of hatchings of cross-sections will be omitted. Numerical values to be exemplified below are merely preferred examples of the present invention, and thus the present invention is not limited to the numerical values exemplified below.
An organic EL display device 100 is described first as a display device according to a first embodiment of the present invention.
(Overall Configuration)
As shown in
The display panel 101 comprises scanning lines LG1, LG2, . . . , LDm that are connected to the scan driving unit 103 and transmit scanning signals (hereinafter, any scanning line is indicated by LG), data lines LD1, LD2, LD3, LDm that are connected to the data driving unit 104 and transmit data signals (hereinafter, any data line is indicated by LD), capacitance lines LC1, LC2, LC3, . . . , LCm that are connected to the capacitance-line driving unit 105 and transmit capacitance line drive signals (hereinafter, any capacitance line is indicated by LC), and drive lines LP1, LP2, LP3, . . . , LPm that are connected to the drive-signal generating unit 106 and transmit drive signals (hereinafter, any drive line is indicated by LP).
The scanning lines LG1 to LGn extend in a substantially row direction and the data lines LD1 to LDm extend in a substantially column direction in
The signal control unit 102 generates a scanning control signal CONT1, a data control signal CONT2, a capacitance line control signal CONT3, a light emission control signal CONT4, and a video data signal DAT that are for controlling reproduction of images based on eternally inputted video signals R, G, B and input control signals for controlling a display of the video signals (a data enable signal DE, a horizontal synchronizing signal Hsync, a vertical synchronizing signal Vsync, and a main clock MCLK).
The generated scanning control signal CONT1 is inputted to the scan driving unit 103. The scanning control signal CONT1 comprises a vertical synchronization start signal that instructs the start of an output of a gate on voltage Von to be described later, a gate clock signal that controls a timing of outputting the gate on voltage Von, and an output enable signal that controls a period that the gate on voltage Von is outputted. The gate on voltage Von and a gate off voltage Voff for switching on/off the switching transistor Q1 comprised in each of the pixels 101a (see
The data control signal CONT2 and the video data signal DAT are inputted to the data driving unit 104. The data control signal CONT2 comprises a horizontal synchronizing start signal that instructs the start of inputting the video data signal DAT and a load signal for inputting the data signal to the data line LD. The data driving unit 104 latches the received video data signal DAT according to the data control signal CONT2, and then generates as appropriate the data signal corresponding to the video data signal DAT and inputs a resultant data signal to the data line LD.
The capacitance line control signal CONT3 is inputted to the capacitance-line driving unit 105. The capacitance line control signal CONT3 generates the capacitance line drive signal for driving the capacitance line LC. The capacitance-line driving unit 105 generates the capacitance line drive signal for driving the capacitance line LC according to the capacitance line control signal CONT3 and inputs a resultant signal to the capacitance line LC.
The light emission control signal CONT4 is inputted to the drive-signal generating unit 106. The light emission control signal CONT4 generates the drive signal for driving the organic-light emitting diode D1 (see
The drive signal is inputted to an anode of the organic-light emitting diode D1 to be described later. A common voltage Vcom is inputted to a cathode of the organic-light emitting diode D1 (see
(Pixel Configuration)
A schematic configuration and an operation of each of the pixels 101a are described with reference to
The switching transistor Q1 is, for example, an n-type TFT and its source S is connected to a sub-wiring branched from the main wiring of the data line LD at, for example, a node N4 and its drain D is connected through a wiring L1 that comprises a node N1 to a gate G of the driving transistor Q2. A gate G of the switching transistor Q1 is connected to a sub-wiring branched from the main wiring of the scanning line LG at, for example, a node N3. The switching transistor Q1 conducts or disconnects between the data line LD and the node N1 depending on a voltage level Vg (a scanning control voltage) of the scanning signal.
One terminal of the capacitor C1 is connected through a part of a wiring that branches at, for example, the node N1 (this is also comprised in the wiring L1) to the wiring L1. The other terminal of the capacitor C1 is connected to a sub-wiring that branches from the main wiring of the capacitance line LC at, for example, a node N5. The capacitance line drive signal is applied to the capacitance line LC from the capacitance-line driving unit 105 described above. A voltage level Vc (a capacitance line drive voltage) of the capacitance line drive signal can be, for example, a ground potential. In other words, the capacitance line LC can be a ground line. In this case, the capacitance-line driving unit 105 can be omitted.
When the voltage level Vg (the scanning control voltage) of the scanning signal inputted to the scanning line LG becomes a high level, the switching transistor Q1 is switched on and charges according to a voltage level Vd (a data drive voltage) of the data signal are injected in the gate G of the driving transistor Q2 through the switching transistor Q1. As a result, the driving transistor Q2 is switched on and a path between the node N3 and the organic-light emitting diode D1 is conducted.
The capacitor C1 maintains the potential of the gate G of the driving transistor Q2 from when the voltage level Vg of the scanning line LG becomes a low level and the switching transistor Q1 is totally switched off to when the voltage level Vg becomes a high level, the switching transistor Q1 is switched on, and the next data signal is inputted. That is, the capacitor C1 holds data inputted to the data line LD for a predetermined period.
The driving transistor Q2 is, for example, an n-type TFT and its drain D is connected to a sub-wiring branched from the main wiring of the drive line LP at, for example, a node N6 and its source S is connected via a node N2 to an anode of the organic-light emitting diode D1. The common voltage Vcom (for example, the ground potential GND) is applied to the cathode of the organic-light emitting diode D1. When the driving transistor Q2 is thus switched on and a supply voltage VDD is applied to the anode, a current I flows in the organic-light emitting diode D1. The organic-light emitting diode D1 thus emits light with a brightness depending on an amount of the current I. When the driving transistor Q2 is switched off, the current does not flow in the organic-light emitting diode D1 and thus light is not emitted.
A layout structure and a layer structure of each of the pixels 101a are described next in detail with reference to
As shown
The scanning line LG is constituted by, for example, a first wiring layer 41 on the transparent substrate 10 (see
A part of the first wiring layer 41 that extends in the substantially row direction or the substantially column direction corresponds to the main wiring of the scanning line LG, the data line LD, the capacitance line LC, or the drive line LP. The part also corresponds to the sub-wiring that branches from the main wiring to connect the main wiring to elements (such as Q1, Q2, and C1) in each of the pixels 101a.
The contact hole wiring 42 and the second wiring layer 43 are, for example, a wiring that guides the data line LD, the capacitance line LC, or the drive line LP on the interlayer insulating film 40 or the three-dimensional wiring RC that extends across the scanning line LG that extends in a substantially vertical direction to the wiring (such as LD, LC, and LP) to electrically connect between the main wiring of the wiring (such as LD, LC, and LP). According to the present embodiment, a part of the contact hole wiring 42 and the second wiring layer 43 that guide the wiring (such as LD, LC, and LP) on the interlayer insulating film 40 are comprised in the sub-wiring and a part that extends across the scanning line LG are comprised in the main wiring.
In this manner, by using the contact hole wiring 42 formed in the interlayer insulating film 40 (see
A redundant wiring 41a (see
The switching transistor Q1 is, for example, a so-called bottom-gate structure thin film transistor (TFT) that is composed of a gate electrode 11 on the transparent substrate 10, a gate insulating film 12 that covers the gate electrode 11, a source electrode 14s and a drain electrode 14d on the gate insulating film 12, and a transparent semiconductor layer 13 between the source electrode 14s and the drain electrode 14d on the gate insulating film 12 (see
A part of the first wiring layer 41 that constitutes the scanning line LG, for example, can be used for the gate electrode 11. A part of the interlayer insulating film 40 can be used for the gate insulating film 12. A part of a transparent semiconductor layer 44 can be used for the transparent semiconductor layer 13, for example. A part of the second wiring layer 43 that constitutes a part of the data line LD can be used for the source electrode 14s, for example. A part of the second wiring layer 43 that constitutes a part of the wiring L1 can be used for the drain electrode 14d, for example. However, the present invention is not limited thereto, and a so-called top-gate structure thin film transistor (TFT) that a part of the second wiring layer 43 is used for the gate electrode 11 and a part of the first wiring layer 41 is used for the source electrode 14s and the drain electrode 14d may be utilized.
Similarly, the driving transistor Q2 is, for example, a so-called bottom-gate structure thin film transistor (TFT) that is composed of a gate electrode 21 on the transparent electrode 10, a gate insulating film 22 that covers the gate electrode 21, the source electrode 24s and a drain electrode 24d on the gate insulating film 22, and a transparent semiconductor layer 23 between the drain electrode 24d and the source electrode 24s on the gate insulating film 22 (see
A part of the first wiring layer 41 that constitutes a part of the wiring L1 can be used for the gate electrode 21, for example. A part of the interlayer insulating film 40 can be used for the gate insulating film 22, for example. A part of the transparent semiconductor layer 44 can be used for the transparent semiconductor layer 23, for example. A part of the second wiring layer 43 that constitutes a part of the drive line LPcan be used for the drain electrode 24d, for example. A part of the second wiring layer 43 that constitutes a part of the wiring L2 can be used for the source electrode 24s, for example. However, the present invention is not limited thereto, and a so-called top-gate structure TFT that a part of the second wiring layer 43 is used for the gate electrode 21 and a part of the first wiring layer 41 is used for the drain electrode 24d and the source electrode 24s may be utilized.
The active matrix substrate 101A according to the present embodiment is a so-called array substrate that comprises a TFT serving as a transistor element.
The capacitor C1 is composed of, for example, a lower electrode 31 on the transparent substrate 10, an upper electrode 33 above the lower electrode 31, and a capacitive insulating film 32 between the lower electrode 31 and the upper electrode 33 (see
Further, the organic-light emitting diode D1 on the active matrix substrate 101A is composed of, for example, the anode electrode 61, the organic film 62 on the anode electrode 61, and the cathode electrode 63 on the organic film 62 (see
A partition wall 70 for partitioning the anode electrode 61 and the organic film 62 for each pixel is formed between adjacent pixels 101a (see
A glass substrate can be used for the transparent substrate 10. However, the present invention is not limited thereto, and various transparent insulating substrates such as a glass substrate, a quartz substrate, and a plastic substrate can be used. When a flexible substrate is used for the transparent substrate 10, a flexible organic EL display device 100 can be realized. The word “transparent” in the present invention means transparent or semi-transparent with respect to light of wavelengths comprised in at least a visible light band.
The first wiring layer 41, the contact hole wiring 42, the second wiring layer 43, and the contact plug 51 are made of a conductive material whose main ingredient is zinc tin oxide (ZTO). However, the present invention is not limited thereto. For example, indium containing oxides (indium tin oxide (ITO) and indium zinc oxide (IZO)), other inorganic oxide conductive materials, and organic conductive materials that can obtain a transparent conductive film can be used. The ZTO material can be used as the conductive material when an amount (a molar amount) of Sn is larger than that of Zn (for example, a Zn:Sn molar ratio of 1:2). ITO as the conductive material generally has an In:Sn molar ratio of about 0.9:0.1. IZO as the conductive material generally has an In:Zn molar ratio of about 0.9:0.1.
A ZTO conductive film is particularly advantageous because it can be formed as an amorphous film and thus the flexible first wiring layer 41, the flexible second wiring layer 43, the flexible contact hole wiring 42, and the flexible contact plug 51 can be realized. Because the amorphous ZTO conductive film can be formed at a low temperature, it can be easily formed even when a substrate with a low resistance to a high temperature, for example, a plastic substrate is used as the transparent substrate 10. Accordingly, forming the first wiring layer 41, the second wiring layer 43, the contact hole wiring 42, and the contact plug 51 by using the ZTO conductive film is appropriate when the flexible organic EL display device 100 is produced.
For example, a transparent insulating single layer film made of a silicon insulating material such as SOG (Spin On Glass), silicon oxide (SiO2), or silicon nitride (SiNx), an aluminum oxide such as alumina (Al2O3), a hafnium oxide such as hafnia (HfO2), a yttrium oxide such as yttria (Y2O3), a lanthanum oxide such as La2O3, or an insulating material that can be formed by a coating process such as a transparent photosensitive resin and a transparent insulating multilayer film that comprises one or more of these materials can be used for the interlayer insulating films 40 and 50. According to the present embodiment, the interlayer insulating film 40 is formed of, for example, an insulating film of a multilayer structure that comprises an alumina (Al2O3) film and a hafnia (HfO2) film and the interlayer insulating film 50 is formed of, for example, a single layer structure insulating film made of a photosensitive resin. According to the present embodiment, the interlayer insulating films 40 and 50 function as a flattening film for securing flatness of the layers, in addition to functioning as an insulating film for insulating between the layers.
The transparent semiconductor layer 44 is formed on the interlayer insulating film 40 so as to cover the second wiring layer 43 and the contact hole wiring 42. The transparent semiconductor layer 44 functions as a protection film for reducing process damages subjected to the underlying second wiring layer 43 and the contact hole wiring 42 during, for example, an etching step at a manufacturing step to be described later. According to the present embodiment, a transparent semiconductor layer made of a semiconductor material that can reduce a carrier density as compared to the wiring made of the conductive material (the ZTO conductive material or the indium containing oxide conductive material) and that is made of ZTO or indium containing oxide is used as the transparent semiconductor layer 44. The ZTO material can be used as the semiconductor material when the (molar) amount of Zn is larger than that of Sn (for example, a Zn:Sn molar ratio of 2:1). When the ZTO semiconductor layer is formed, the carrier density of the semiconductor layer is adjusted to be low by increasing an oxygen density of an atmosphere. Because the ZTO transparent semiconductor layer can be also formed as an amorphous film like the first wiring layer 41 described above, the flexible transparent semiconductor layer 44 can be realized, which is appropriate for forming the flexible organic EL display device 100. However, the present invention is not limited such a ZTO semiconductor material, and various transparent semiconductor materials comprising a transparent inorganic oxide semiconductor material such as an indium containing oxide semiconductor material (for example, IZO with an In:Zn molar ratio of 4:6) and a transparent organic semiconductor material such as a precursor of pentacene or tetrabenzoporphyrine.
According to the present embodiment, a material of the same type is used for the main ingredient of a conductive material that forms the transparent semiconductor layer 44 and the main ingredient of a conductive material that forms an electrode that contacts the transparent electrode in the respective elements. Accordingly, in the present embodiment, the second wiring layer 43 that comprises the source electrode 14s and the drain electrode 14d and the source electrode 24s and the drain electrode 24d is formed of a ZTO conductive film whose main ingredient is ZTO, and the transparent semiconductor layer 44 is formed of a ZTO semiconductor film whose main ingredient is ZTO and whose carrier density is lower than that of the second wiring layer 43. By forming these layers with the material of the same type, the source electrode 14s or the drain electrode 14d can ohmic contact the transparent semiconductor layer 13 in the switching transistor Q1. Similarly, the drain electrode 24d or the source electrode 24s can ohmic contact the transparent semiconductor layer 23 in the driving transistor Q2. Resistance components of the TFT elements (such as Q1 and Q2) are thus reduced and the drive power of the TFT elements can be reduced. Consequently, consumption power of the organic EL display device 100 can be reduced.
The partition wall 70 can be formed of, for example, an insulating film of a single layer structure made of a photosensitive resin. However, the present invention is not limited thereto, and a transparent insulating single layer film made of a silicon insulating material such as SOG, SiO2, or SiNx, an aluminum oxide such as Al2O3, a hafnium oxide such as HfO2, a yttrium oxide such as Y2O3, a lanthanum oxide such as La2O3, or an insulating material that can be formed by a coating process such as a transparent photosensitive resin and a transparent insulating multilayer film that comprises one or more of these materials can be used.
Because the switching transistor Q1, the driving transistor Q2, and the capacitor C1 can be composed of using a part of the first wiring layer 41, the second wiring layer 43, and the interlayer insulating film 40 described above, their materials can be same as those described above. Appropriate modifications such as forming a transparent conductive film for reducing the resistance of the electrodes on the electrodes can be made.
In the organic-light emitting diode D1, the organic film 62 is, for example, a stacked film of a multilayer structure that comprises a hole injection layer, a hole transporting layer, an organic light emitting layer, an electron transporting layer, an electron injection layer, and a hole barrier layer. In the organic film 62, various light emitting materials such as macromolecular materials such as polyfluorene, derivatives and copolymers thereof, polyarylene, derivatives and copolymers thereof, polyarylene vinylene, derivatives and copolymers thereof, polyarylamine, derivatives and copolymers thereof, various fluorescent or phosphorescent low molecular light emitting materials or macromolecular materials may be used for a host material of the organic light emitting layer according to combinations with the hole transporting layer and a target wavelength.
A transparent single layer film made of an oxide conductive material such as ZTO or ITO or a metal material such as silver (Ag) or aluminum (Al) and a transparent stacked film of a multilayer structure that comprises these materials can be used for the anode electrode 61 placed on the light outputting side. When the metal material is used, a layer that comprises this material is made thin so that light is transmitted. According to the present embodiment, a case that a stacked film of ZTO/Ag/ZTO is used and an Ag film in this film is made thin so as to transmit light is described. The cathode electrode 63 can be obtained by using a conductive material such as metal that has a high conductivity and a high reflectance such as silver (Ag), aluminum (Al), or magnesium (Mg) or alloy thereof. A case that an alloy film of Mg and Ag is used is described in the present embodiment.
The passivation film 80 can be formed by using a multilayer film of an SiO2 film and an SiNx film formed by a CVD method. A case that the multilayer film of the SiO2 film and the SiNx film is used is provided in the present embodiment.
As is clear from the above descriptions, according to the organic EL display device 100 according to the present embodiment, all layers placed on the bottom surface 100a side, that is, the light outputting side with respect to the organic film 62 are formed of transparent films or semi-transparent films that transmit light. A so-called full-aperture organic EL display device 100 that the entire region of the bottom surface 100a serving as a light outputting surface is open can be realized.
(Manufacturing Method)
A method for manufacturing the organic EL display device 100 according to the present embodiment is described next in detail with reference to the drawings.
According to this manufacturing method, the transparent substrate 10 is prepared first and ZTO is then deposited on one of two main surfaces that are vertical to a thickness direction of the substrate (a vertical direction to the substrate) (hereinafter, this surface is determined as a top surface) by using, for example, sputtering method, CVD (Chemical Vapor Deposition) method, or vacuum deposition method, so that a transparent amorphous ZTO conductive film is formed. The ZTO conductive film is then patterned by using, for example, photolithography method (in the present specification, “photolithography method” can comprise a patterning step such as an etching step), so that the gate electrodes 11 and 21, the lower electrode 31, the first wiring layer 41, and the redundant wiring 41a (see
Alumina (Al2O3) and hafnia (HfO2) are then successively deposited on the top surface of the transparent substrate 10 with the electrodes and the wiring (such as 11, 21, 31, 41, and 41a) being formed thereon by, for example, sputtering method, CVD method, or vacuum deposition method, so that the interlayer insulating film 40 formed of a transparent insulating stacked film is formed (a first interlayer insulating film forming step). The interlayer insulating film 40 is then patterned by, for example, photolithography method. As shown in
ZTO is then deposited on the interlayer insulating film 40 with the contact holes apl and ap2 being formed therein by, for example, sputtering method, CVD method, or vacuum deposition method, so that a transparent amorphous ZTO conductive film is formed. At this time, the ZTO conductive film may be formed in the contact hole ap2. This ZTO conductive film is then patterned by, for example, photolithography method, so that the source electrode 14s and the drain electrode 14d, the drain electrode 24d and the source electrode 24s, the upper electrode 33, and the second wiring layer 43 are formed on the interlayer insulating film 40, and the contact hole wiring 42 electrically connected to the first wiring layer 41 is formed in the contact hole ap1 of the interlayer insulating film 40, as shown in
ZTO is then deposited on the interlayer insulating film 40 with the electrodes and the wiring (such as 14s, 14d, 24d, 24s, 33, 42, and 43) being formed thereon by, for example, sputtering method, CVD method, or vacuum deposition method, so that a ZTO semiconductor film whose carrier density is lower than that of the ZTO conductive film is formed (a semiconductor layer forming step). At this time, the ZTO semiconductor film may be formed in the contact hole ap2. As described above, by controlling the molar ratio of Zn and Sn, the ZTO semiconductor film can be a transparent semiconductor film whose carrier density is lower than the ZTO conductive film that constitutes the first wiring layer 41 and the second wiring layer 43. This ZTO semiconductor film is then patterned by photolithography method, so that the transparent semiconductor layer 44 that covers the electrodes and the wiring (such as 14s, 14d, 24d, 24s, 33, 42, and 43) is formed on the interlayer insulating film 40 as shown in
Because the transparent semiconductor layer 44, the second wiring layer 43, and the contact hole wiring 42 are made of a material of the same type in the present embodiment, an appropriate selection ratio of the transparent semiconductor layer 44 to the second wiring layer 43 during etching is difficult to be obtained. In the present embodiment, the transparent semiconductor layer 44 after patterning covers the second wiring layer 43 and the contact hole wiring 42. Accordingly, the second wiring layer 43 and the contact hole wiring 42 are not exposed to an etching atmosphere during etching. The transparent semiconductor layer 44 can thus be patterned without considering a selection ratio to the second wiring layer 43. However, the present invention is not limited thereto. For example, the transparent semiconductor layer 44 can be formed by using the coating process technique described above. In this case, the formed transparent semiconductor layer does not need to be patterned by etching, and thus the transparent semiconductor layer 44 does not need to cover the second wiring layer 43 and the contact hole wiring 42.
As described above, when the transparent semiconductor layer (such as 13, 23, and 44) is formed, a photosensitive resist liquid is then spin coated on the interlayer insulating film 40 with the transparent semiconductor layer (such as 13, 23, and 44) being formed thereon, and a resultant film is exposed to light and developed. As shown in
ZTO is then deposited on the interlayer insulating film 50 with the contact hole ap3 being formed therein by, for example, sputtering method, CVD method, or vacuum deposition method. As shown in
By performing the steps described above, the active matrix substrate 101A as an array substrate is manufactured in the present embodiment.
ZTO, Ag, and ZTO are successively deposited on the active matrix substrate 101A by, for example, sputtering method, CVD method, or vacuum deposition method, so that a transparent ZTO/Ag/ZTO stacked film with an electrical contact to the contact plug 51 is formed. The ZTO/Ag/ZTO stacked film is then patterned by photolithography method, so that the anode electrode 61 electrically connected to the contact plug 51 is formed on the interlayer insulating film 50 as shown in
A photosensitive resist liquid is then spin coated on the active matrix substrate 101A with the anode electrode 61 being formed thereon, and a resultant substrate is exposed to light and developed. As shown in
The hole injection layer, the hole transport layer, the organic light emitting layer, the electron transport layer, the electron injection layer, and the hole block layer are then successively stacked at least on the anode electrode 61 by existing film forming techniques. As shown in
An alloy material of Mg and Ag is then deposited on the entire active matrix substrate 101A with the organic film 62 and the partition wall 70 being formed thereon by vacuum deposition method, so that a conductive alloy film is formed. At this time, an excessive alloy film is prevented from being deposited on regions other than a desired region by a shadow mask method. As shown in
A multilayer film of SiO2 and SiNxis formed on the entire top surface of the active matrix substrate 101A with the organic-light emitting diode D1 that is composed of the anode electrode 61 and the organic film 62 partitioned by the partition wall 70, and the cathode electrode 63 being formed thereon by CVD method. The passivation film 80 that protects the underlying elements (such as Q1, Q2, C1, and D1) and the wiring (such as LG, LP, L1, and L2) is thus formed. A substrate is attached to the top surface of the passivation film 80 that is opposite to the side the substrate 101A is placed for sealing. Alternatively, a film is formed by sputtering method or CVD method for sealing. By the steps described above, the display panel 101 that comprises the pixel 101a with the layer structure shown in
Thereafter, the display panel 101 manufactured by the method described above is mounted to a housing in which the signal control unit 102, the scan driving unit 103, the data driving unit 104, the capacitance-line driving unit 105, the drive-signal generating unit 106, and other components are incorporated, so that the organic EL display device 100 according to the present embodiment is manufactured.
While the above manufacturing step comprises a step of washing a substrate and the like as appropriate, these steps will be omitted to simplify the descriptions.
As described above, according to the organic EL display device 100 of the present embodiment, all films on the bottom surface 100a side serving as the light outputting side of the organic film 62 are formed of films that transmit light. A bottom emission type organic EL display device 100 whose light outputting surface is fully open, that is, of a so-called full-aperture type can be realized.
Because the light outputting surface is fully open, the arrangement of a light emitting element (the organic-light emitting diode D1 according to the present embodiment) can be freely designed. The organic EL display device 100 with greater flexibility in design can be realized.
Further, according to the manufacturing method of the present embodiment, the contact hole wiring 42 and the second wiring layer 43 are covered by the transparent semiconductor layer 44 in the manufacturing process. Process damages subjected to the wiring (such as 42 and 43) at a subsequent etching step can be reduced.
Furthermore, layers that constitute the organic EL display device 100 may be formed by using a flexible material in the present embodiment.
While the present embodiment of the present invention describes the organic EL display device 100 that a light emitting layer (the organic film 62 according to the present embodiment) is made of an organic material, the present invention is not limited thereto, and an inorganic EL display device that the light emitting layer is made of an inorganic material can be provided.
An organic EL display device is then described as a display device according to a second embodiment of the present invention. In the present embodiment, the organic EL display device that can output light from a light emitting element (for example, an organic-light emitting diode D2 in
A functional configuration of the organic EL display device according to the present embodiment is the same as the schematic functional block configuration of the organic EL display device 100 shown in
(Pixel Configuration)
A layout structure and a layer structure of each of the pixels 201a are described next in detail. The layout structure of the active matrix substrate 101A in the pixel 201a according to the present embodiment is the same as that of the pixel 101a shown in
As is clear from a comparison of
The cathode electrode 65 can be made of an electrode material that can transmit visible light like, for example, the anode electrode 61. A transparent single layer film made of an oxide conductive material such as ZTO or ITO or a metal material such as silver (Ag) or aluminum (Al) and a transparent stacked film with a multilayer structure that comprises these materials can be used for the electrode material. When the metal material is used, a layer that comprises the metal material is a thin semi-transmissive film that transmits light. According to the present embodiment, a case that an alloy film of Mg and Ag is used and the cathode electrode is formed of a thin film that transmits light is described. In this manner, in addition to the bottom emission configuration of the first embodiment of the present invention, the cathode electrode 65 is constituted by a transparent electrode. A so-called dual emission type organic EL display device that can output light from the bottom surface 100a and the top surface 200a of the display panel 101 can thus be realized.
The auxiliary electrode 66 on the cathode electrode 65 is formed in a region on the active matrix substrate 101A where each of the pixels 201a is partitioned (for example, above the partition wall 70). A single layer film made of an inorganic oxide conductive material such as ZTO or ITO or a metal material such as silver (Ag) or aluminum (Al) and a stacked film with a multilayer structure that comprises these materials can be used for the auxiliary electrode material. When the auxiliary electrode 66 is placed on the region of each of the pixels 201a as in the present embodiment, the auxiliary electrode 66 does not need to be made of a transparent electrode material and can be made of a high conductive material such as Al or Ag. A case that the auxiliary electrode 66 is formed by using a conductive single layer film made of ZTO is described in the present embodiment. Because the auxiliary electrode 66 that reduces the resistance of the cathode in the organic-light emitting diode D2 is provided, a drive voltage of the organic-light emitting diode D2 can reduced. As a result, consumption power of the organic EL display device can be reduced. Because the transparent electrode material is used for the auxiliary electrode 66, a so-called dual full-aperture organic EL display device that the entire top surface 200a as well as the bottom surface 100a is open can be realized.
(Manufacturing Method)
A method for manufacturing the organic EL display device according to the present embodiment is obtained by substituting the step of forming the cathode electrode 63 shown in
At the step of forming the cathode electrode 65, a thin alloy film of Mg and Ag is deposited on the entire active matrix substrate 101A manufactured with reference to
At the step of forming the auxiliary electrode 66, after the cathode electrode 65 is formed as at the step described above, an oxide conductive material such as ZTO or ITO or metal with a low resistance such as Ag, Al, or Cu is deposited at least on the cathode electrode 65 by sputtering method using shadow mask method, CVD method, or vacuum deposition method. As a result, the auxiliary electrode 66 is formed in the region on the top surface of the cathode electrode 65 above the partition wall 70.
After the passivation film 80 is formed as in the first embodiment of the present invention, the manufactured display panel 101 is mounted to the housing in which the signal control unit 102, the scan driving unit 103, the data driving unit 104, the capacitance-line driving unit 105, and the drive-signal generating unit 106 are incorporated, so that the organic EL display device of the present embodiment is manufactured.
While the manufacturing step described above comprises a step of washing a substrate and the like as appropriate, these steps will be omitted to simplify the descriptions.
As described above, according to the organic EL display device of the present embodiment, all layers on the top surface 200a side and the bottom surface 100a side serving as light outputting sides of the organic film 62 are formed of films that transmit light. A so-called full-aperture dual emission type organic EL display device whose light outputting surface is fully open can be realized.
Because the entire light outputting surface is open, the arrangement of a light emitting element (the organic-light emitting diode D2 according to the present embodiment) can be freely designed. An organic EL display device with greater flexibility in design can be realized. Further, because the organic EL display device of the present embodiment comprises the auxiliary electrode 66 for reducing the resistance of the cathode electrode 65, the drive voltage of the organic-light emitting diode D2 can be reduced and thus consumption power of the organic EL display device can be reduced. Further, the organic EL display device according to the present embodiment can be used for various purposes, for example, as a display used by attached to a transparent surface such as a window of a vehicle, a glass window, or a glass water tank.
Further, according to the method for manufacturing the present embodiment, the contact hole wiring 42 and the second wiring layer 43 are covered by the transparent semiconductor layer 44 in the manufacturing process as in the first embodiment of the present invention. Process damages subjected to the wiring (such as 42 and 43) at a subsequent etching step can be reduced.
Furthermore, as in the first embodiment of the present invention, layers that constitute the organic EL display device 100 can be formed by using flexible materials in the above embodiment.
According to the present embodiment, an inorganic EL display device that a light emitting layer is made of an inorganic material can be provided as in the first embodiment of the present invention. Further, according to the present embodiment, a reflection film (a reflector) is provided on a layer on the top or bottom side serving as one light emitting side, so that a top emission type or a bottom emission type organic EL display device with improved brightness can be realized.
A liquid-crystal display device 300 is then described as a display device according to a third embodiment of the present invention.
(Overall Configuration)
As shown in
Configurations of the signal control unit 102, the scan driving unit 103, the data driving unit 104, and the capacitance-line driving unit 105 are the same as those of the first embodiment of the present invention. A scanning control signal CONT1, a data control signal CONT2, a capacitance line control signal CONT3, and a video data signal DAT are generated as appropriate as signals that match a driving method of the liquid crystal element and outputted. In the present embodiment, the drive line LP, the drive-signal generating unit 106, and the light emission control signal CONT4 can be omitted.
The display panel 301 is connected to the scanning line LG, the data line LD, and the capacitance line LC. According to the present embodiment, In the scanning line LG, the data line LD, and the capacitance line LC, a part of a wiring that extend so as to intersect with other lines are called main wiring, and a part of a wiring that branches from the main wiring to be connected to a switching transistor Q31 or a storage capacitor C31 in each of the pixels 301a (see
(Pixel Configuration)
A schematic configuration and an operation of each of the pixels 301a are described next with reference to
The switching transistor Q31 is, for example, an n-type TFT and its source S is connected to the sub-wiring that branches from the main wiring of the data line LD at, for example, a node N34 and its drain D is connected to a wiring L31 that comprises a node N31. A gate G of the switching transistor Q31 is connected to a sub-wiring that branches from the main wiring of the scanning line LG at, for example, a node N33. The switching transistor Q31 conducts or disconnects between the data line LD and the node N31 according to a voltage level Vg (a scanning control voltage) of a scanning signal.
One terminal of the storage capacitor C31 is connected to the wiring L31 through a part of a wiring that branches at, for example, the node N31 (this is also comprised in the wiring L31). The other terminal of the storage capacitor C31 is connected to a sub-wiring that branches from the main wiring of the capacitance line LC at, for example, a node N35. A capacitance line drive signal that is outputted from the capacitance-line driving unit 105 is applied to the capacitance line LC as in the first embodiment of the present invention. A voltage level Vc (a capacitance line drive voltage) of the capacitance line drive signal can be, for example, a ground potential. For example, the capacitance line is connected to a GND (Vcom) terminal that is the same common electrode as that of the liquid crystal element Cpx (E31). That is, the capacitance line LC can be a ground line. In this case, the capacitance-line driving unit 105 can be omitted.
One electrode of the liquid crystal element E31 (for example, a pixel electrode 311 in
When the voltage level Vg (the scanning control voltage) of the scanning signal inputted to the scanning line LG becomes a high level, the switching transistor Q31 is switched on and charges are injected in the pixel electrode 311 (see
The storage capacitor C31 functions to maintain the potential of the pixel electrode 311 from when the voltage level Vg of the scanning line LG becomes a low level and the switching transistor Q31 is completely switched off to when the voltage level Vg becomes a high level again, the switching transistor Q31 is switched on, and the next data signal is inputted. That is, the storage capacitor C31 holds a data signal SD inputted to the data line LD for a predetermined period.
A so-called inversion driving method in which a polarity of the data signal inputted to the data line LD and a potential of the capacitance line drive signal inputted to the capacitance line LC are inverted for every predetermined period can be utilized in the present embodiment. While examples of the inversion driving method comprise a dot inversion driving method and a line inversion driving method, any of the inversion driving methods can be utilized.
A layout structure and a layer structure of each of the pixels 301a are described next in detail with reference to
As shown in
The scanning line LG, the data line LD, the capacitance line LC, and the wiring L31 are respectively constituted by at least a part of the first wiring layer 41, the contact hole wiring 42, the second wiring layer 43, and the contact plug 51 as in the first embodiment of the present invention. The switching transistor Q31 is composed of a gate electrode 15 that is a part of the first wiring layer 41 that constitutes the scanning line LG, a gate insulating film 16 that is a part of the interlayer insulating film 40, a source electrode 18s that is a part of the second wiring layer 43 that constitutes a part of the data line LD, a drain electrode 18d that is a part of the second wiring layer 43 that constitutes a part of the wiring L31, and a transparent semiconductor layer 17 that is a part of the transparent semiconductor layer 44. Further, the storage capacitor C31 is constituted by a lower electrode 35 that is a part of the first wiring layer 41 that constitutes the wiring L31, a capacitive insulating film 36 that is a part of the interlayer insulating film 40, and an upper electrode 37 that is a part of the second wiring layer 43 that constitutes the capacitance line LC. The nodes N31 and N33 to N35 shown in
While the switching transistor Q31 according to the present embodiment is a so-called bottom-gate structure TFT like the switching transistor Q1 according to the first embodiment of the present invention, the present invention is not limited to this case and a top-gate structure TFT can be used. The active matrix substrate 301A according to the present embodiment is a so-called array substrate like the active matrix substrate 101A according to the first embodiment of the present invention.
The redundant wiring 41a provided by making a part of the first wiring layer 41 redundant (see
Further, the liquid crystal element E31 on the active matrix substrate 301A with the above configuration is composed of, for example, the pixel electrode 311, the liquid crystal layer 312 above the pixel electrode 311, the common electrode 313 above the liquid crystal layer 312, and the alignment films 314 and 315 that sandwich the liquid crystal layer 312 in a vertical direction (see
Furthermore, the polarizing plates 330 and 340 that sandwich the active matrix substrate 301A and the opposing substrate 302A are provided at outer sides of the substrates 301A and 302A. The light source 350 is placed below the active matrix substrate 301A. Accordingly, light from the light source 350 passes through the polarizing plate 330, the active matrix substrate 301A, the liquid crystal element E31, the color filter 64, the opposing substrate 302A, and the polarizing plate 340 to be outputted externally from a top surface 300a that is the light outputting surface of the display panel 301. In
The first wiring layer 41, the interlayer insulating film 40, the transparent semiconductor layer 44, and the second wiring layer 43 can be made of the same materials as those of the first embodiment of the present invention. The switching transistor Q31 and the storage capacitor C31 can be also made of the same materials. The transparent substrate 10, the contact hole wiring 42, the contact plug 51, and the interlayer insulating film 50 can be made of the same materials as those of the first embodiment of the present invention.
Various filter materials comprising a photosensitive resin prepared by mixing predetermined pigments so that wavelengths of bands appropriate for R, G, and B pixels 301a are transmitted can be used for the color filter 64. The present embodiment describes a case that a transparent photosensitive resin prepared by mixing predetermined pigments according to the respective pixels 301a is used.
In the liquid crystal element E31 on the active matrix substrate 301A, various materials such as esters, biphenyls, phenylcyclohexanes, cyclohexanes, phenylpyrimidines, and dioxanes can be used for a base material of the liquid crystal layer 312. The liquid crystal layer 312 is formed by mixing the aforementioned base material with materials according to purposes.
An oxide conductive material such as ZTO or ITO can be used for the pixel electrode 311. The present embodiment describes a case of using a transparent conductive film made of ZTO. In addition, an oxide conductive material such as ZTO or ITO can be used for the common electrode 313 like the pixel electrode 311. The present embodiment describes an example of using a transparent conductive film made of ZTO.
The alignment film 314 and 315 are for aligning the molecular arrangement of the liquid crystal layer 312 in a fixed direction and appropriately made of a material such as polyimide according to the material used for the liquid crystal layer 312.
The dielectric projection 316 controls the arrangement direction of liquid crystal molecules when a bias voltage is applied to the liquid crystal layer 312, and is provided in a protruded manner from the top surface of the liquid crystal layer 312 toward its inner side so as to oppose the central portion of the pixel electrode 311 with the liquid crystal layer 312 interposed therebetween. The dielectric projection 316 can be formed by using a dielectric material such as a photosensitive resin.
The light shielding film 321 can be formed of a metal film such as chromium (Cr) or a photosensitive resist film such as a black resist in which a light shielding dispersion pigment typified by carbon black is dispersed. The present embodiment describes a case of forming the film 321 by using Cr.
A spacer 317 secures a space where the liquid crystal between the active matrix substrate 301A and the opposing substrate 302A is sealed, and can be formed by using, for example, a photosensitive resin. However, the present invention is not limited thereto.
The polarizing plates 330 and 340 are filters that are vertical to a light traveling direction and transmit light that vibrates intensively in a particular direction, and can be formed by a polyvinyl alcohol (PVA) film that iodine (I) is absorbed. However, the present invention is not limited thereto.
The opposing substrate 302A is composed of, for example, a transparent substrate 320. Various transparent insulating substrates such as a glass substrate, a quartz substrate, and a plastic substrate can be used for the transparent substrate 320. A flexible substrate can be used as the transparent substrate 320.
(Manufacturing Method)
A method for manufacturing the liquid-crystal display device 300 according to the present embodiment is described next in detail with reference to the drawings.
First, according to this manufacturing method, the active matrix substrate 301A that comprises the switching transistor Q31 and the storage capacitor C31 is manufactured by the same steps as the steps described in the first embodiment of the present invention with reference to
ZTO is then formed on the active matrix substrate 301A by, for example, sputtering method or CVD method, so that a transparent ZTO film that comprises an electrical contact to the contact plug 51 is formed. The ZTO film is then patterned by photolithography method, so that the pixel electrode 311 electrically connected to the contact plug 51 is formed on the interlayer insulating film 50 as shown in
Next, for example, a polyimide solution is then spin coated on the active matrix substrate 301A with the pixel electrode 311 being formed thereon and dried to solidify it. A resultant polyimide film is then rubbed by rubbing method. As shown in
Thereafter, a sealing material for preventing flow of a liquid crystal material is formed around the region on the active matrix substrate 301A where the pixels 301a are arranged. Various steps comprising a step of coating a transfer can be performed if necessary.
According to this manufacturing method, the transparent substrate 320 for the opposing substrate 302A is prepared and Cr is deposited on one of two main surfaces vertical to a thickness direction of the substrate (hereinafter, this is called top surface) by, for example, sputtering method, CVD method, or vacuum deposition method, so that a light shielding chromium film is formed. The chromium film is then patterned by photolithography method, so that the light shielding film 321 that has a light shielding property as a black matrix is formed in the region above the active matrix substrate 301A where the pixel 301a is partitioned as shown in
Next, a photosensitive resist liquid with which a predetermined pigment is mixed according to R, G, or B is spin coated on the opposing substrate 302A with the light shielding film 321 being formed thereon, and a step of exposing to light and developing a resultant substrate is repeated. As shown in
Next, ZTO is formed on the opposing substrate 302A with the color filter 64 being formed thereon by sputtering method or CVD method, so that a transparent ZTO film is formed. By removing an excessive ZTO film by photolithography method, as shown in
A polyimide solution is then spin coated on the opposing substrate 302A with the common electrode 313 being formed thereon and dried to solidify it. A resultant polyimide film is then rubbed by rubbing method, so that the alignment film 315 is formed as shown in
A photosensitive resist liquid is then spin coated on the opposing substrate 302A with the alignment film 315 being formed thereon and a resultant substrate is exposed to light and developed. Consequently, a corner of the resultant resin film is formed into the triangular shaped dielectric projection 316 on the alignment film 315 by increasing a post-bake temperature, as shown in
A photosensitive resist liquid is then spin coated on the opposing substrate 302A with the dielectric projection 316 being formed thereon, and a resultant substrate is exposed to light and developed. As shown in
As described above, when the active matrix substrate 301A with the pixel electrode 311 and the alignment film 314 being formed thereon and the opposing substrate 302A with the light shielding film 321, the color filter 64, the common electrode 313, the alignment film 315, the dielectric projection 316, and the spacer 317 being formed thereon are manufactured, a liquid crystal is loaded into the region on the opposing substrate 302A surrounded by the sealing material. As shown in
Next, the polarizing plates 330 and 340 made of polyvinyl alcohol (PVA) that iodine (I) is absorbed are prepared and attached to the active matrix substrate 301A and the opposing substrate 302A, respectively so as to sandwich the liquid crystal layer 312. The display panel 301 that comprises the pixel 301a with the layer structure shown in
Thereafter, the display panel 301 manufactured by the manner described above is mounted to the housing in which the signal control unit 102, the scan driving unit 103, the data driving unit 104, the capacitance-line driving unit 305, and other components are incorporated, so that the liquid-crystal display device 300 according to the present embodiment is manufactured.
While the manufacturing step described above comprises a step of washing a substrate and the like as appropriate, these steps will be omitted to simplify the descriptions.
As described above, according to the liquid-crystal display device 300 of the present embodiment, all the layers other than the light shielding film 321 serving as a black matrix are formed of films that transmit light. The aperture ratio of the display panel 301 in the liquid-crystal display device 300 can be improved significantly. Because the light shielding film 321 is formed appropriately if necessary, a full-aperture display panel can be realized in a liquid-crystal display device that does not require a black matrix.
Because the aperture ratio is improved, the flexibility in the arrangement of the liquid crystal element E31 and the light source 350 is also improved. The liquid-crystal display device 300 with greater flexibility in design can be realized.
Further, according to the manufacturing method for the present embodiment, the contact hole wiring 42 and the second wiring layer 43 are covered by the transparent semiconductor layer 44 in the manufacturing process as in the first or second embodiment of the present invention. Process damages subjected to the wiring (such as 42 and 43) at a subsequent etching step can thus be reduced.
The above embodiments are only examples for carrying out the present invention and the present invention is not limited to these embodiments. Various modifications made according to specifications and the like are within the scope of the invention, and it is obvious from the above descriptions that various other embodiments can be made within the scope of the present invention.
10, 320 transparent substrate
11, 21, 15 gate electrode
12, 22, 16 gate insulating film
13, 23, 17 transparent semiconductor layer
14
d,
18
d,
24
d drain electrode
14
s,
18
s,
24
s source electrode
31, 35 lower electrode
32, 36 capacitive insulating film
33, 37 upper electrode
40, 50 interlayer insulating film
41 first wiring layer
41
a redundant wiring
42 contact hole wiring
43 second wiring layer
44 transparent semiconductor layer
51 contact plug
61 anode electrode
62 organic film
63, 65 cathode electrode
64 color filter
66 auxiliary electrode
70 partition wall
80 passivation film
100 organic EL display device
100
a bottom surface
101, 301 display panel
101A, 301A active matrix substrate
101
a,
201
a,
301
a pixel
200
a,
300
a top surface
300 liquid-crystal display device
302A opposing substrate
311 pixel electrode
312 liquid crystal layer
313 common electrode
314, 315 alignment film
316 dielectric projection
317 spacer
321 light shielding film
330, 340 polarizing plate
C1 capacitor
C31 storage capacitor
D1, D2 organic-light emitting diode
E31 liquid crystal element
LD data line
LG scanning line
LP drive line
LC capacitance line
L1, L2, L31 wiring
Q1, Q31 switching transistor
Q2 driving transistor
RC three-dimensional wiring
Number | Date | Country | Kind |
---|---|---|---|
2008-192607 | Jul 2008 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2009/062922 | 7/16/2009 | WO | 00 | 1/20/2011 |