The disclosed technology is in connection with an array substrate of a thin film transistor liquid crystal display (TFT-LCD) and a method for manufacturing the same, and the array substrate comprises: a base substrate; a gate line and a data line forming on the base substrate and defining a pixel region, a pixel electrode, a thin film transistor and a common electrode are formed in the pixel region; a black matrix made of conductive thin film material, the black matrix is electrically connected with the common electrode.
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13. A method for manufacturing an array substrate of the TFT-LCD, comprising:
step 1, forming a gate line, a data line, a pixel electrode and a thin film transistor on a base substrate;
step 2, forming a common electrode and a black matrix on the base substrate after step 1, the black matrix is electrically connected with the common electrode; and
step 3, depositing an anti-reflection layer on a surface of the black matrix.
1. An array substrate of a thin film transistor liquid crystal display (TFT-LCD), comprising:
a base substrate;
gate lines and data lines forming on the base substrate and defining pixel regions, wherein a pixel electrode, a thin film transistor, and a common electrode which forms a multi-dimensional space composite field together with the pixel electrode, are disposed in each of the pixel regions, and
a black matrix made of a conductive material, wherein the black matrix is electrically connected with the common electrode,
wherein an anti-reflection layer is deposited on a surface of the black matrix.
2. The array substrate of the TFT-LCD according to
3. The array substrate of the TFT-LCD according to
4. The array substrate of the TFT-LCD according to
5. The array substrate of the TFT-LCD according to
6. The array substrate of the TFT-LCD according to
7. The array substrate of the TFT-LCD according to
8. The array substrate of the TFT-LCD according to
9. The array substrate of the TFT-LCD according to
10. The array substrate of the TFT-LCD according to
11. The array substrate of the TFT-LCD according to
12. The array substrate of the TFT-LCD according to
14. The method according to
depositing a gate metal thin film on the base substrate, and patterning the gate metal thin film to form the gate line and a gate electrode;
depositing a gate insulating layer, a semiconductor thin film and a doped semiconductor thin film in sequence on the base substrate, and forming an active layer for the thin film transistors by a patterning process, wherein the active layer comprises the semiconductor layer and doped semiconductor layer and is formed on the gate insulating layer and above the gate electrode;
depositing a transparent conductive thin film on the base substrate and patterning the transparent conductive thin film to form the pixel electrode; and
depositing a source and drain metal thin film on the base substrate and patterning the source and drain metal thin film to form the data line, and a source electrode, a drain electrode and a channel region of the thin film transistor, wherein one end of the source electrode is located on the active layer, and the other end is connected with the data line, one end of the drain electrode is located on the active layer, and the other end is directly connected with the pixel electrode, and the channel region is defined between the source electrode and the drain electrode.
15. The method of
depositing a passivation layer and a transparent conductive thin film on the base substrate after step 1, and patterning the transparent conductive thin film to form the common electrode, wherein the common electrode comprises a plurality of strip electrodes arranged in sequence; and
depositing a black matrix conductive thin film on the base substrate on which the common electrode has formed, and patterning the black matrix conductive thin film to form the black matrix, wherein the black matrix is electrically connected with the common electrode.
16. The method of
depositing a passivation layer on the base substrate after step 1, and then depositing the transparent conductive thin film and the black matrix conductive thin film in sequence;
coating a photoresist layer on the black matrix conductive thin film;
exposing the photoresist layer by using a half-tone mask plate or a gray-tone mask plate, developing the photoresist layer to form a completely remained photoresist region, a completely removed photoresist region, and a partially remained photoresist region, wherein the completely remained photoresist region corresponds to the region in which the black matrix pattern exists, the partially remained photoresist region corresponds to the region in which the common electrode pattern exists, and the completely removed photoresist region corresponds to the region except for the above patterns;
etching the black matrix conductive thin film and the transparent conductive thin film in the completely removed photoresist region by a first etch process to form the black matrix;
removing the photoresist in the partially remained photoresist region by an ashing process, to expose the black matrix conductive thin film in this region;
completely removing the black matrix conductive thin film in the partially remained photoresist region by a second etching process to form the common electrode; and
removing the remaining photoresist.
17. The method of
depositing a passivation layer and a black matrix conductive thin film on the base substrate after step 1, and patterning the black matrix conductive thin film to form the black matrix; and
depositing a transparent conductive thin film on the base substrate on which the black matrix has been formed, and patterning a transparent conductive thin film to form the common electrode, wherein the common electrode comprise a plurality of strip electrodes arranged in sequence and are electrically connected with the black matrix.
18. The method of
19. The method of
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Embodiments of the disclosed technology relate to an array substrate of a thin film transistor liquid crystal display and a method for manufacturing the same.
In the thin film transistor liquid crystal display (TFT-LCD) technology, Advanced-Super Dimensional Switching (AD-SDS) is one of the technologies for improving the display quality of a LCD.
An AS-SDS LCD forms a multi-dimensional space composite field by a parallel electric field generated by edges of pixel electrodes in the same plane and a vertical electric field generated between common electrodes and pixel electrodes, so that liquid crystal molecules between the pixel electrodes within a liquid crystal unit and immediately above the electrodes can rotate in all orientations, thereby improving work efficiency of in-plane orientation type liquid crystal and increasing the light transmission efficiency. AS-SDS can improve the display quality of a TFT-LCD, and has advantages of high transmittance, wide viewing angle, high aperture ratio, low chromatic aberration, short response time, free of push Mura, etc.
The main structure of a TFT-LCD typically comprises an array substrate and a color filter substrate forming a liquid crystal cell with a liquid crystal layer interposed therebetween. Gate lines, data lines, pixel electrodes, thin film transistors, and common electrodes of a strip structure are formed on the array substrate. A color resin pattern and a black matrix pattern are formed on the color filter substrate, and the black matrix pattern is mainly used to block the light leakage area. In the structure of an early AD-SDS TFT-LCD, the black matrix pattern on the color filter substrate is usually prepared with a resin material. A width of the black matrix is determined mainly based on the width of the data lines on the array substrate. With an improving requirement of LCD aperture ratio, the width of the data lines becomes narrower and narrower, so the black matrix of the resin material gradually becomes one of the main factors of blocking the increase of aperture ratio.
To increase aperture ratio, it has been proposed that the black matrix pattern is prepared with a metal material. Although this technology can reduce the width of the black matrix, the metal black matrix may lead to electric field distortion and reducing display quality of the AD-SDS TFT-LCD. To avoid electric field distortion, it has been proposed a technology of connecting the black matrix on the color filter substrate with the common electrode on array substrate. Specifically, during preparing the color filter substrate and the array substrate, via holes are opened in overcoat layers respectively so as to form transfer dots, the black matrix on the color filter substrate is electrically connected to the common electrode on array substrate through the transfer dots. However, in operation, this technology not only gives rise to high cost, but also incurs common electrode delay defect or the like. Firstly, it is necessary to have extra procedures and extra patterning apparatus for the fabrication of the transfer dots, so the production cost is increased. Secondly, since the common electrode and the black matrix are located on different substrates, respectively, and are connected with each other through the transfer dots, this structure causes a significant delay in the common electrode, and making this technology difficult for the application such as a large-sized display, a liquid crystal TV set, and so on.
An embodiment of the disclosed technology provides an array substrate of TFT-LCD, comprising: a base substrate; gate lines and data lines forming on the base substrate and defining pixel regions, wherein a pixel electrode, a thin film transistor, and a common electrode which forms a multi-dimensional space composite field together with the pixel electrode, are disposed in each of the pixel regions, and a black matrix made of a conductive material, wherein the black matrix is electrically connected with the common electrode.
Another embodiment of the disclosed technology further provides a method for manufacturing an array substrate of TFT-LCD, comprising: step 1, forming a gate line, a date line, a pixel electrode and a thin film transistor on a base substrate; and step 2, forming a common electrode and a black matrix on the base substrate after step 1, the black matrix is electrically connected with the common electrode.
Further scope of applicability of the disclosed technology will become apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the disclosed technology, are given by way of illustration only, since various changes and modifications within the spirit and scope of the disclosed technology will become apparent to those skilled in the art from the following detailed description.
The disclosed technology will become more fully understood from the detailed description given hereinafter and the accompanying drawings which are given by way of illustration only, and thus are not limitative of the disclosed technology and wherein:
The disclosed technology is further described in detail by the following drawings and embodiments. The thickness of respective thin film layer and the size of regions in the drawings do not show a real ratio of an array substrate of TFT-LCD, and it is only for the purpose of illustrating the content of the disclosed technology.
As
Specifically, each pixel region of the array substrate of the TFT-LCD according to the embodiment of the disclosed technology comprises the gate line 11 and a gate electrode 2 formed on the base substrate 1, the gate electrode 2 is connected with the gate line 11; a gate insulating layer 3 is formed on the gate line 11 and the gate electrode 2 and covers the entire base substrate 1; an active layer (comprising a laminated structure of a semiconductor layer 4 and a doped semiconductor layer 5) of the thin film transistor is formed on the gate insulating layer 3 and is located above the gate electrode 2; the pixel electrode 13 is formed on the gate insulating layer 3 and is located within respective pixel region; one end of a source electrode 6 of the thin film transistor is located on the active layer, and the other end is connected with the date line 12, while one end of a drain electrode 7 is located on the active layer, and the other end is connected with the pixel electrode 13, and a TFT channel region is defined between the source electrode 6 and the drain electrode 7, the doped semiconductor layer 5 in the channel region is completely removed, and a part of the thickness of the semiconductor layer 4 is also removed, so that the semiconductor layer 4 in the channel region is exposed; a passivation layer 8 is formed on the resultant structure and covers the entire base substrate 1; the common electrode 14 is formed on the passivation layer 8; the black matrix 9 is formed on the above resultant structure, is located above the gate line 11, the date line 12, and the thin film transistor, and is directly connected with the common electrode 14.
In the above embodiment, the pixel electrode 13 is in a plate shape. However, the pixel electrode 13 also may have a plurality of slits parallel with each other, corresponding to the strip electrodes of the common electrode 14; or, the pixel electrode 13 also may comprise a plurality of strip electrodes parallel with each other, and space between the strip electrodes of the pixel electrode 13 corresponds to the strip electrode of the common electrode 14.
Firstly, a gate metal thin film is deposited on the base substrate 1 (e.g., a glass substrate or quartz substrate) by a magnetron sputtering method or a thermal evaporating method, and then the gate metal thin film is patterned by a patterning process using a common mask, so as to form a pattern comprising the gate line 11 and the gate electrode 2 connected to the gate line 11, as shown in
The gate insulating layer, the semiconductor thin film and the doped semiconductor thin film are deposited in sequence on the base substrate with the pattern as shown in
A transparent conductive thin film is deposited on the base substrate with the pattern as shown in
A source and drain metal thin film is deposited on the base substrate with the pattern as shown in
The passivation layer 8 is deposited on the base substrate with the pattern as shown in
Finally, the black matrix metal thin film is deposited on the base substrate with the pattern as shown in
Since the black matrix of the present embodiment is made of a metal material, one reflection preventing layer may further be applied on a surface of the black matrix in order to prevent light reflection from the black matrix.
It should be note that the structure shown in
Further, the processes shown in
Firstly, the passivation layer 8 is deposited by a PECVD method, and then the transparent conductive thin film 21 and the black matrix metal thin film 22 are sequentially deposited by a magnetron sputtering method or a thermal evaporating method. A photoresist layer 20 is coated on the black matrix metal thin film, and is exposed by using a half-tone mask plate or a gray tone mask plate, and the developed photoresist 20 comprises a unexposed region A (completely remained photoresist region), a completely exposed region B (completely removed photoresist region), and a partially exposed region C (partially remained photoresist region), as shown in
Finally, the remaining photoresist is removed, and the fifth patterning process for the array substrate of the TFT-LCD according to the first embodiment of the disclosed technology is completed, as shown in
As
An embodiment of the disclosed technology provides an array substrate of a TFT-LCD, on which the black matrix pattern is disposed. The black matrix is connected with the common electrode, so that the black matrix can effectively block the light leakage area and work as the connection bus line of the common electrode, thus the defects such as high structure cost and the common electrode delay can be overcome. Since the black matrix formed of a metal thin film material is formed above the gate line, the data line, the source electrode and the drain electrode, the width of the black matrix can be reduced and aperture ratio can be improved. The black matrix and the common electrode are disposed on the array substrate and directly connected with each other, so the common electrode delay can be completely eliminated. Thus, the array substrate of the TFT-LCD can be widely applied to the applications such as a large-sized display and a liquid crystal TV set, or the like.
An embodiment of a method for manufacturing an array substrate of the TFT-LCD of the disclosed technology, the method comprises the following steps:
Step 1, forming a pattern comprising a gate line, a data line, a pixel electrode and a thin film transistor on a base substrate; and
Step 2, forming a pattern comprising a common electrode and a black matrix on the base substrate after step 1, the black matrix being electrically connected with the common electrode.
The embodiment of the disclosed technology provides an array substrate of a TFT-LCD. The black matrix pattern is disposed on the array substrate and is connected with the common electrode, so that the black matrix can not only effectively block the light leakage area but also work as the connection bus line of the common electrode, thus the defects such as the high structure cost and the common electrode delay can be overcome. Since the black matrix pattern can be prepared on the array substrate by conventional processes apparatus and process procedures, there is no need for additional production apparatuses. Also, the apparatus and processes for preparing the black pattern on the color filter substrate can be eliminated, so the production cost of the disclosed technology can be effectively reduced.
The above step 1 may further comprise:
Step 11, depositing a gate metal thin film on the base substrate, and forming the pattern comprising the gate line and a gate electrode by patterning the gate metal thin film;
Step 12, depositing the gate insulating layer, the semiconductor thin film and the doped semiconductor thin film in sequence on the base substrate after step 11, and forming the pattern comprising the active layer by a patterning process, wherein the active layer comprises the laminated layer structure of the semiconductor layer and the doped semiconductor layer and is formed on the gate insulating layer and above the gate electrode;
Step 13, depositing the transparent conductive thin film on the base substrate after step 12, and forming the pattern comprising the pixel electrode by a patterning process;
Step 14, depositing the source and drain metal thin film on the substrate after step 13, and forming the pattern comprising the date line, and the source electrode, the drain electrode and the channel region of the thin film transistor by a patterning process, wherein one end of the source electrode is located on the active layer, and the other end is connected with the date line; one end of the drain electrode is located on the active layer, and the other end is directly connected with the pixel electrode; the channel region is defined between the source electrode and the drain electrode.
The above preparation procedure has been described in detail in the embodiment as shown in
In the first example of the method for manufacturing the array substrate according to the embodiment of the disclosed technology, the step 2 comprises:
Step 211, depositing the passivation layer and the transparent conductive thin film on the base substrate after step 1, and patterning the transparent conductive thin film to form the pattern comprising the common electrode by the patterning process using a common mask plate, the common electrode comprises a plurality of strip electrodes arranged in sequence;
Step 212, depositing the black matrix metal thin film on the substrate after step 211, and patterning the black matrix metal thin film to form the pattern comprising the black matrix by the patterning process using a common mask plate, wherein the black matrix is connected with the common electrode.
This example is to form the black matrix pattern and the common electrode pattern by two patterning processes, the black matrix is located above the common electrode, and the preparation procedure has been described in detail in the embodiment as shown in
In the second example of the method for manufacturing the array substrate according to the embodiment of the disclosed technology, the step 2 comprises:
Step 221, firstly depositing the passivation layer on the base substrate after step 1, and then continuously depositing the transparent conductive thin film and the black matrix metal thin film;
Step 222, coating a photoresist layer on the black matrix metal thin film;
Step 223, exposing the photoresist layer by a half-tone mask plate or a gray tone mask plate, developing the photoresist layer to form a completely remained photoresist region, a completely removed photoresist region, and a partially remained photoresist region; wherein the completely remained photoresist region corresponds to the region in which the black matrix pattern exists, the partially remained photoresist region corresponds to the region in which the common electrode pattern exists, and the completely removed photoresist region corresponds to the region except for the above patterns.
Step 224, etching the black matrix metal thin film and the transparent conductive thin film in the completely removed photoresist region B by a first etch process, to form the pattern comprising the black matrix;
Step 225, removing the photoresist in the partially remained photoresist region by an ashing process, to expose the black matrix metal thin film in this region;
Step 226, completely removing the black matrix metal thin film in the partially remained photoresist region by a second etching process to form the pattern comprising the common electrode; and
Step 227, removing the remaining photoresist.
The present example is to form the black matrix pattern and the common electrode pattern by one patterning process, the black matrix is located above the common electrode, and the preparation procedure has been described in detail in the embodiment as shown in
In the third example of the method for manufacturing the array substrate according to the embodiment of the disclosed technology, the step 2 comprises:
Step 231, depositing the passivation layer and the black matrix metal thin film on the base substrate after step 1, and patterning the black matrix metal thin film to form the pattern comprising the black matrix by the patterning process using a common mask plate;
Step 232, depositing the transparent conductive thin film on the base substrate after step 231, and patterning the transparent conductive thin film to form the pattern comprising common electrode by the patterning process using a common mask plate, the common electrode comprises a plurality of strip electrodes arranged in sequence and is connected with the black matrix.
The present example is to form the black matrix pattern and the common electrode pattern by two patterning processes, and the common electrode is located above the black matrix.
Since the black matrix in the embodiment of the disclosed technology comprises a metal material, in order to prevent the light reflection from the black matrix, a step of applying one anti-reflection layer on the surface of the black matrix can be added behind the step 2.
In the embodiment of the disclosed technology, the black matrix also may be made of a non-metal conductive thin film material, such as carbon nanotube material.
The conductivity of the conductive thin film material for forming the black matrix may be higher than that of the common electrode.
The black matrix also may be horizontally connected with the common electrode and formed in the same layer.
It should be noted that: the above description is only for the purpose of explaining the disclosed technology but not for a limitation, although the disclosed technology has been described in detail with reference to the preferred embodiments, those skilled in the art should understand that change and alternation can be made in the technologies of the disclosed technology without depart from the spirit and scope of the disclosed technology.
Kim, Young Min, Kim, Won Seok, Kim, Pil Seok
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
6466281, | Aug 23 1999 | Transpacific IP Ltd | Integrated black matrix/color filter structure for TFT-LCD |
6522315, | Feb 17 1997 | Intellectual Keystone Technology LLC | Display apparatus |
20020101557, | |||
20040263754, | |||
20040266082, | |||
20070126953, | |||
20070252142, | |||
20070273819, | |||
20080002126, | |||
20080309864, | |||
20100003776, | |||
20100040960, | |||
20100320464, | |||
CN100517033, | |||
CN101078824, | |||
CN101097925, | |||
CN1369731, | |||
JP10186407, | |||
JP2003207808, |
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