CN100371816C - TFT array substrate of liquid crystal display, liquid crystal display panel and its mfg. method - Google Patents
TFT array substrate of liquid crystal display, liquid crystal display panel and its mfg. method Download PDFInfo
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- CN100371816C CN100371816C CNB2005100568468A CN200510056846A CN100371816C CN 100371816 C CN100371816 C CN 100371816C CN B2005100568468 A CNB2005100568468 A CN B2005100568468A CN 200510056846 A CN200510056846 A CN 200510056846A CN 100371816 C CN100371816 C CN 100371816C
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Abstract
The present invention relates to an array substrate of a thin film transistor (TFT) of a liquid crystal display, which comprises a substrate, a grid electrode, a dielectric layer of the grid electrode, a semi-conductor layer, a source electrode and a leakage electrode, wherein the grid electrode is positioned on the substrate, the dielectric layer of the grid electrode covers an AND gate (grid) electrode of the substrate; the semiconductor layer is positioned on the dielectric layer of the grid electrode, and the semiconductor layer comprises a trench; the source electrode is electrically connected with part of the semiconductor layer on one side of the trench; the leakage electrode is electrically connected with part of the semiconductor layer on the other side of the trench, and the leakage electrode is not overlapped with the grid electrode on the orthographic projection surface. The TFT structure provided by the present invention has smaller coupling capacitance, and can improve the problem of feed through effect in public-known technique; besides, the present invention also provides a light shielding layer which can reduce the problem of electricity leakage of the structure produced by light irradiation.
Description
Technical field
The present invention relates to LCD and preparation method thereof, particularly thin film transistor (TFT) of LCD (TFT:Thin Film Transistor) and preparation method thereof.
Background technology
LCD (LCD:liquid crystal display) is the main flow of present flat-panel screens development, its displaying principle is dielectric anisotropy and the electric anisotropy that utilizes liquid crystal molecule to have, when extra electric field, make the ordered state conversion of liquid crystal molecule, cause liquid crystal film to produce various photoelectric effect.The panel construction of LCD is generally by two plate bases and is formed by stacking, and the space of certain distance is left in order to the perfusion liquid crystal in the centre, and is being formed with counter electrode respectively on the two substrates up and down, turning to and arranging in order to the control liquid crystal molecule.Be illustrated in figure 1 as the planimetric map of thin-film transistor structure in the prior art.LCD uses thin film transistor (TFT) as gauge tap, and wherein grid 102 is overlapped in source electrode 106 and drain electrode 104 at frontal plane of projection.But because there are a coupling capacitance (below can be described as Cgd) in the grid 102 of thin film transistor (TFT) and drain electrode 104 ends, can be the pixel current potential is drop-down when grid 102 is closed by coupling capacitance, this is called feedthrough effect (feed through effect).
In general, coupling capacitance is bigger, and feedthrough effect (feed through effect) is just more serious.In the past, use to increase storage capacitors Cst improving the feedthrough effect, but the increase of storage capacitors Cst can cause aperture opening ratio to reduce.In addition, when the situation of exposure skew or etching inequality takes place, can cause coupling capacitance Cgd homogeneity not good, and cause non-uniform phenomenon shot mura, or produce flicker (flicker) phenomenon at the mask joint.Reduce coupling capacitance Cgd and can improve above-mentioned shortcoming, less in addition coupling capacitance Cgd is because coupling capacitance Cgd inequality causes the situation of mura also slighter.
Summary of the invention
Therefore,, the object of the present invention is to provide a kind of TFT structure, can reduce coupling capacitance Cgd, with the variety of problems of improving feedthrough effect (feed through effect) or causing because of Cgd is excessive according to the problems referred to above.
The invention provides a kind of tft array substrate of LCD.Comprise: a substrate; One grid is positioned on this substrate; One gate dielectric covered substrate and gate pole (grid); Semi-conductor layer is positioned on the gate dielectric, and semiconductor layer comprises a raceway groove; One light shield layer is arranged in described semiconductor layer; One source pole is electrically connected the part semiconductor layer of raceway groove one side; One drain electrode is electrically connected the part semiconductor layer of raceway groove opposite side, and drain electrode is at frontal plane of projection discord gate overlap.
The invention provides a kind of method for making of tft array substrate of LCD.At first, provide a substrate, form a grid on substrate; Form a gate dielectric covered substrate and gate pole (grid); Form a conductive layer (light-shielding material layers) in gate dielectric laminar surface or top; Remove the conductive layer of grid top, expose gate dielectric to form an opening; Form semi-conductor layer on conductive layer, and insert opening, wherein semiconductor layer comprises a raceway groove; Form a doping semiconductor layer on semiconductor layer; Graphical doping semiconductor layer and semiconductor layer so that doping semiconductor layer and semiconductor layer at least one pleurapophysis of frontal plane of projection for grid; With the doping semiconductor layer is mask, the etching conductive layer, with form a light shield layer in semiconductor layer with the shield portions semiconductor layer; Form one source pole, be electrically connected the part semiconductor layer of raceway groove one side; Form a drain electrode, be electrically connected the part semiconductor layer of raceway groove opposite side, wherein drain at frontal plane of projection discord gate overlap.
The invention provides a kind of display panels, this panel comprises:
One first substrate;
One second substrate is with respect to this first substrate;
One thin film transistor (TFT) is arranged on described first substrate, and this thin film transistor (TFT) comprises:
One grid is positioned on described first substrate;
One gate dielectric covers this substrate and described grid;
Semi-conductor layer is positioned on the described gate dielectric, and this semiconductor layer comprises a raceway groove;
One light shield layer is arranged in described semiconductor layer;
One source pole is electrically connected the part semiconductor layer of described raceway groove one side;
One drain electrode is electrically connected the part semiconductor layer of described raceway groove opposite side, and this drain electrode is at frontal plane of projection this gate overlap of getting along well; And
One liquid crystal layer is sandwiched between described first substrate and second substrate.
Beneficial effect of the present invention is, tft array substrate provided by the invention, and its grid and drain electrode do not overlap each other, and have less coupling capacitance (Cgd), can improve the problem of feedthrough effect in the prior art (feed througheffect).In addition, the present invention provides a light shield layer can reduce the problem of this kind structure because of the electric leakage that illumination produced in addition.
Description of drawings
Fig. 1 is the planimetric map of thin-film transistor structure in the prior art;
Fig. 2 A is the partial top view of one embodiment of the invention thin film transistor (TFT) tft array substrate;
Fig. 2 B is the partial bottom view of one embodiment of the invention thin film transistor (TFT) tft array substrate;
Fig. 2 C is the partial rear view of one embodiment of the invention thin film transistor (TFT) tft array substrate;
Fig. 3 A to Fig. 3 L is the schematic flow sheet of one embodiment of the invention thin film transistor (TFT) tft array substrate;
Fig. 4 is the bias voltage and the coupling capacitance Cgd graph of a relation of TFT structure and one embodiment of the invention TFT structure in the prior art;
Fig. 5 has the bias voltage and the closed condition current relationship figure of the TFT structure of the TFT structure of light shield layer and no light shield layer for one embodiment of the invention;
Fig. 6 A is the partial top view of another embodiment of the present invention thin film transistor (TFT) tft array substrate;
Fig. 6 B is the sectional view along 6B-6B ' among Fig. 6 A;
Fig. 7 A is the partial top view of another embodiment of the present invention thin film transistor (TFT) tft array substrate;
Fig. 7 B is the sectional view along 7B-7B ' among Fig. 7 A;
Fig. 8 A is the partial top view of another embodiment of the present invention thin film transistor (TFT) tft array substrate;
Fig. 8 B is the sectional view along 8B-8B ' among Fig. 8 A.
[symbol description]
Contacting metal pad 306; Gate dielectric 308;
Protective seam 330; Transparency conducting layer 332;
Raceway groove 712; Gate insulator 714;
Embodiment
Below will describe the present invention in detail with embodiment.At icon or in describing, similar or identical part use same reference numbers.In icon, the shape of embodiment or thickness can enlarge, to simplify or convenient the sign.The part of assembly will illustrate to describe in the icon, and the assembly that does not illustrate or describe is the known form of those skilled in the art.In addition, when narration one deck was positioned at a substrate or another layer and goes up, this layer can be located immediately on substrate or another layer, or also intermediary layer can be arranged therebetween.
Fig. 2 A is the partial top view of one embodiment of the invention thin film transistor (TFT) tft array substrate.Fig. 2 B is the partial bottom view of one embodiment of the invention thin film transistor (TFT) tft array substrate.Fig. 3 I is the sectional view of one embodiment of the invention thin film transistor (TFT) tft array substrate.Please refer to Fig. 2 A, 2B and 3I, a grid 302 is positioned on the substrate 300, and this grid 302 can be connected to a gate line 202.One gate dielectric, 308 cover gate 302 and substrate 300.One light shield layer 318 is positioned at gate dielectric 308 surfaces or top, and light shield layer 318 and gate dielectric 308 can accompany a photoresist layer.In one embodiment, on the frontal plane of projection of substrate 300, light shield layer 318 contact grids 302 to cover semiconductor layer 314 fully, prevent that leakage current from taking place.In another embodiment, on the frontal plane of projection of substrate 300, light shield layer 318 is adjacent to grid 302, and has a gap d between the two, shown in Fig. 2 C.In one embodiment, semiconductor layer 314 cover part gate dielectrics 308 and light shield layer 318.Because consider raceway groove, in the frontal plane of projection direction, semiconductor layer 314 needs to protrude in an end of grid 302 at least.
Because semiconductor layer 314 is photoactive substances, it is easily because of producing photocurrent (photo current) behind the irradiation, cause the TFT leakage current excessive, so one embodiment of the invention proposes a TFT structure, its light shield layer 318 is arranged in outstanding semiconductor layer 314 and is adjacent to gate dielectric 308, to avoid the TFT electric leakage.One source pole 322 is positioned at semiconductor layer 314 tops, and on the frontal plane of projection of substrate 300 lap grid 302.One drain electrode 324 is positioned at semiconductor layer 314 tops, and is not overlapped in grid 302 on the frontal plane of projection of substrate 300.In one embodiment, on frontal plane of projection, the only at one end outstanding grid 302 of semiconductor layer 314, and the part of the 324 overlapping semiconductor layer 314 outstanding grids 302 that drain with the overlapping area of minimizing because of grid and drain electrode, and reduces coupling capacitance Cgd.In one embodiment, on the back projection face, grid 302 and light shield layer 318 hide semiconductor layer 314 fully, to avoid semiconductor layer 314 because of irradiation produces electric leakage, shown in Fig. 2 B.In addition, source electrode 322 or drain 324 and 314 of semiconductor layers can accompany a doping semiconductor layer 316, so that lower contact resistance to be provided.
Fig. 3 A to Fig. 3 L is the schematic flow sheet of one embodiment of the invention thin film transistor (TFT) tft array substrate.At first, please refer to Fig. 3 A, substrate 300, for example a glass substrate is provided.The preferably, substrate 300 can be alkali-free glass substrate or glass with lower alkali content substrate.Then, form a first metal layer (not illustrating) on substrate 300 with a deposition process.Conductive layer (the first metal layer) can be Ta, Mo, W, Ti, Cr, Al or its combination or its stack layer.The method of above-mentioned deposition one conductive layer can be a sputtering method (physical vapor deposition) (PVD:Physica1 Vapor Deposition) or ion growth form chemical vapor deposition (PECVD:Plasma Enhancement Chemical Vapor Deposition).With the first metal layer on known exposure and the graphical substrate of developing method, to form grid 302, storage capacitors bottom electrode 304 and contacting metal pad 306.
Please refer to Fig. 3 B, deposit a gate dielectric 308 on grid 302, storage capacitors bottom electrode 304, contacting metal pad 306 and substrate 300.This gate dielectric 308 can be monox, silicon nitride, silicon oxynitride or its combination.Next, shown in Fig. 3 C, form a photoresist layer 310 on gate dielectric 308 with a figure cloth method.The preferably, photoresist layer 310 is negative photoresistance, so that subsequent handling can be by the substrate back definitions component of exposing.On photoresist layer 310, deposit a light-shielding material layers 312 then.Light-shielding material layers 312 can be Ta, Mo, W, Ti, Cr, Al or its combination or its stack layer, and the preferred approach of deposition light-shielding material layers 312 is a low temperature process, and for example: the method for above-mentioned deposition one light-shielding material layers 312 can be a sputtering method (physical vapor deposition) (PVD:Physical Vapor Deposition) or ion growth form chemical vapor deposition (PECVD:Plasma Enhancement Chemical Vapor Deposition).
Shown in Fig. 3 D, be mask with the conductive layer (grid 302, storage capacitors bottom electrode 304, contacting metal pad 306) after graphical, expose 311 from substrate 300 back sides, with the graphical photoresist layer 310 of self-aligned (self-alignment) mode.Carry out peel off (lift-off) step thereafter.In this embodiment, because photoresist layer 310 is a negative photoresistance, can adopt a developing method to remove the unexposed photoresist layer 310 in graphical back conductive layer (grid 302, storage capacitors bottom electrode 304, contacting metal pad 306) top, and because unexposed photoresist layer 310 is removed, light-shielding material layers 312 on the stripping photolithography glue-line 310 in the lump, and graphical photoresist layer 310 and light-shielding material layers 312, above corresponding grid 302, storage capacitors bottom electrode 304, contacting metal pad 306, to form corresponding opening.Like this, can reduce by a mask, but the invention is not restricted to this.The present invention also can not adopt the method for peeling off (lift-off), and uses the method for general photoetching and etching, graphical light-shielding material layers 312.
Shown in Fig. 3 E, deposit semi-conductor layer 314 on second metal level (light-shielding material layers) 312, and insert in the above-mentioned opening, its opening corresponds respectively to grid 302, storage capacitors bottom electrode 304 and contacting metal pad 306.Deposit a doping semiconductor layer 316 on semiconductor layer 314.In one embodiment, semiconductor layer 314 can be formed by silicon, germanium, polysilicon or compound crystal silicon.In addition, doping semiconductor layer 316 can be at silicon or germanium semiconductor Doping Phosphorus or arsenic, makes its semiconductor layer that becomes n+, so that the subsequent metal layer excellent contact to be provided.
Shown in Fig. 3 F, with known photoetching and graphical doped semiconductor 316 of lithographic method and semiconductor layer 314.In this step, remove above the grid 302 and adjoining zone and storage capacitors bottom electrode 304 above outside doped semiconductor 316 and semiconductor layer 314.Particularly, on frontal plane of projection, Yi Bian doped semiconductor 316 and semiconductor layer 314 have the grid of protruding in 302 at least.In the present embodiment, Yi Bian doping semiconductor layer 316 and semiconductor layer 314 are protruding in grid 302, but the invention is not restricted to this.Shown in Fig. 3 G, be mask with graphical back doping semiconductor layer 316, carry out an anisotropic etching, etching second metal level (light-shielding material layers) 312 and the photoresist layer 310 under it.In this embodiment, second metal level (light-shielding material layers) that is arranged in semiconductor layer 314 is made for light shield layer 318, shines semiconductor layer 314 to prevent backlight, produces photocurrent, causes electric leakage.
Then, shown in Fig. 3 H, deposition 1 the 3rd conductive layer 320 of the blanket property covered is on doped semiconductor 316 and gate dielectric 308.The 3rd conductive layer 320 can be Ta, Mo, W, Ti, Cr, Al or its combination or its stack layer.Then, shown in Fig. 3 I,,, and on storage capacitors 326, form storage capacitors top electrode 328 with formation source electrode 322 and drain electrode 324 above semiconductor layer 314 with known photoetching and graphical the 3rd conductive layer 320 of lithographic method and doping semiconductor layer 316.Particularly, on frontal plane of projection, drain electrode 324 is not overlapped in grid 302, to reduce coupling capacitance Cgd.In one embodiment, the 32 4 part tops that are positioned at the outstanding grids 302 of semiconductor layer 314 that drain.
Then, shown in Fig. 3 J, deposition one protective seam 330 of the blanket property covered is on source electrode 322, drain electrode 324, storage capacitors top electrode 328 and gate dielectric 308.Protective seam 330 can be made up of silicon nitride or silicon oxynitride.Afterwards, graphical protective seam 330 and storage capacitors top electrode 328.Particularly above storage capacitors 326 and contact mat 306, respectively form corresponding opening.Shown in Fig. 3 K, deposition one transparency conducting layer 332 of the blanket property covered and is inserted in the above-mentioned opening on protective seam 320, to be electrically connected with storage capacitors top electrode 328 and contact mat 306.Transparency conducting layer 332 can be that ITO (indium-tin oxide film) forms.Shown in Fig. 3 L, graphical transparency conducting layer 332 is connected in storage capacitors 326 to form pixel electrode 332a, and contact electrode 332b connects contact mat 306.
Fig. 4 is the bias voltage and the coupling capacitance Cgd graph of a relation of TFT structure and one embodiment of the invention TFT structure (the TFT structure of Fig. 2 A) in the prior art.As shown in Figure 4, the coupling capacitance Cgd of one embodiment of the invention structure 402 is lower by about 80% than prior art.Fig. 5 has the bias voltage and the closed condition current relationship figure of the TFT structure of the TFT structure 406 of light shield layer and no light shield layer 408 for one embodiment of the invention.As shown in Figure 5, when Vds is 10V, there is the TFT structure 406 of light shield layer can effectively reduce the leakage current of embodiment of the invention TFT really.
Fig. 6 A is the partial top view of another embodiment of the present invention thin film transistor (TFT) tft array substrate.Fig. 6 B is the sectional view along 6B-6B ' among Fig. 6 A.This embodiment of the present invention is similar in appearance to the embodiment of Fig. 2 A, and promptly drain electrode 602 discord grids 604 are overlapping on frontal plane of projection.And a light shield layer 606 is arranged in semi-conductor layer 608, to reduce leakage current.Its difference is that source electrode 610 centers on drain electrode 602 for half arc, and both are at a distance of a constant spacing.Semiconductor layer 608 is positioned at source electrode 610 and drain electrode 602 belows, and its subregion can be overlapping in frontal plane of projection and source electrode 610, drain electrode 602.The semiconductor layer 608 that is positioned between source electrode and drain electrode is the raceway groove 612 of TFT.Grid 604 is arranged in the gate insulator 614 of source electrode 610, drain electrode 602 and semiconductor layer 608 belows, and is adjacent to a substrate 600.What pay special attention to is not overlap each other at frontal plane of projection grid 604 and drain electrode 602.
Fig. 7 A is the partial top view of another embodiment of the present invention thin film transistor (TFT) tft array substrate.Fig. 7 B is the sectional view along 7B-7B ' among Fig. 7 A.This embodiment of the present invention is similar in appearance to the embodiment of Fig. 2 A, and promptly drain electrode 702 discord grids 704 are overlapping on frontal plane of projection.And a light shield layer 706 is arranged in semi-conductor layer 708, to reduce leakage current.Its difference is, draining in this embodiment 702 is one L shaped, and source electrode 710 is one L shaped, and both are at a distance of a constant spacing.Semiconductor layer 708 is positioned at source electrode 710 and drain electrode 702 belows, and its subregion can be overlapping in frontal plane of projection and source electrode 710, drain electrode 702.Be positioned at source electrode 710 and the gap of 702 semiconductor layers 708 that drain is the raceway groove 712 of TFT.Grid 704 is arranged in the gate insulator 714 of source electrode 710, drain electrode 702 and semiconductor layer 708 belows, and is adjacent to a substrate 700.What pay special attention to is not overlap each other at frontal plane of projection grid 704 and drain electrode 702.
Fig. 8 A is the partial top view of another embodiment of the present invention thin film transistor (TFT) tft array substrate.Fig. 8 B is the sectional view along 8B-8B ' among Fig. 8 A.This embodiment of the present invention is similar in appearance to the embodiment of Fig. 2 A, and promptly drain electrode 802 discord grids 804 are overlapping on frontal plane of projection.And a light shield layer 806 is arranged in semi-conductor layer, to reduce leakage current.Its difference is, draining in this embodiment 802 is a rectangle, and source electrode 810 is one hook-shaped, and both are at a distance of a constant spacing.Semiconductor layer 808 is positioned at source electrode 810 and drain electrode 802 belows, and its subregion can be overlapping in frontal plane of projection and source electrode 810, drain electrode 802.Be positioned at source electrode 802 and 810 the part semiconductor layer in gap of draining is the raceway groove 812 of TFT.Grid 804 is arranged in the gate insulator 814 of source electrode 810, drain electrode 802 and semiconductor layer 808 belows, and is adjacent to a substrate 800.What pay special attention to is not overlap each other at frontal plane of projection grid 804 and drain electrode 802.
In addition, the formed tft array substrate of the foregoing description is the part of a display panels.LCD also includes a upper substrate with respect to tft array substrate.In one embodiment, upper substrate can be colored filter substrate.Between tft array substrate (can be described as infrabasal plate) and upper substrate, can accompany a liquid crystal layer at this.This part is as well known to those skilled in the art, and for simplifying, it is not illustrated among the figure.
The TFT structure that the embodiment of the invention provides, its grid and drain electrode do not overlap each other, and therefore TFT structure provided by the present invention has less coupling capacitance (Cgd), can improve feedthrough effect (feedthrough effect) problem of known technology.In addition, the present invention provides a light shield layer can reduce the problem because of electric leakage that illumination produces of this kind structure in addition.
The foregoing description only is used to illustrate the present invention, and is not to be used to limit the present invention,
Claims (19)
1. the tft array substrate of a LCD is characterized in that comprising:
One substrate;
One grid is positioned on this substrate;
One gate dielectric covers described substrate and described grid;
Semi-conductor layer is positioned on the described gate dielectric, and this semiconductor layer comprises a raceway groove;
One light shield layer is arranged in described semiconductor layer;
One source pole is electrically connected the part semiconductor layer of described raceway groove one side; And
One drain electrode is electrically connected the part semiconductor layer of described raceway groove opposite side, and this drain electrode is at the frontal plane of projection described gate overlap of getting along well.
2. the tft array substrate of LCD as claimed in claim 1 is characterized in that, described light shield layer is in abutting connection with described gate dielectric, and this light shield layer covers the zone of described semiconductor layer beyond frontal plane of projection and described gate overlap.
3. the tft array substrate of LCD as claimed in claim 1 is characterized in that, described light shield layer is made up of opaque metal.
4. the tft array substrate of LCD as claimed in claim 2 is characterized in that, described light shield layer and described gate dielectric interlayer also accompany a photoresist layer.
5. the tft array substrate of LCD as claimed in claim 4 is characterized in that, described photoresist layer is made up of negative photoresist.
6. the tft array substrate of LCD as claimed in claim 1 is characterized in that, described semiconductor layer at frontal plane of projection one pleurapophysis for described grid, and the part of the outstanding grid of the overlapping described semiconductor layer of described drain electrode.
7. the tft array substrate of LCD as claimed in claim 1 is characterized in that,
Described source electrode is half arc, and around described drain electrode, and both are at a distance of a constant spacing;
Described semiconductor layer is positioned at described source electrode and described drain electrode below, and its subregion is overlapping in frontal plane of projection and described source electrode, drain electrode; And
The semiconductor layer that is positioned between source electrode and drain electrode is the described raceway groove of described thin film transistor (TFT).
8. the tft array substrate of LCD as claimed in claim 1 is characterized in that,
Described drain electrode is the L type;
Described source electrode is an inverted L shape, and both are at a distance of a fixed interval (FI);
Described semiconductor layer is positioned at described source electrode and described drain electrode below, and its subregion is overlapping in frontal plane of projection and described source electrode, drain electrode; And
The semiconductor layer that is positioned between source electrode and drain electrode is the described raceway groove of described thin film transistor (TFT).
9. the tft array substrate of LCD as claimed in claim 1 is characterized in that,
Described drain electrode is the square type;
Described source electrode is for colluding type, and the part of this source electrode and described drain electrode are at a distance of a fixed interval (FI);
Described semiconductor layer is positioned at described source electrode and described drain electrode below, and its subregion is overlapping in frontal plane of projection and the described source electrode of part, drain electrode; And
The semiconductor layer that is positioned between source electrode and drain electrode is the described raceway groove of described thin film transistor (TFT).
10. the method for making of the tft array substrate of a LCD is characterized in that comprising:
One substrate is provided;
Form a grid on this substrate;
Form a gate dielectric and cover described substrate and grid;
Form a light-shielding material layers in described gate dielectric laminar surface or top;
Remove the light-shielding material layers of described grid top, expose described gate dielectric to form an opening;
Form semi-conductor layer on this light-shielding material layers, and insert described opening, this semiconductor layer comprises a raceway groove;
Form a doping semiconductor layer on this semiconductor layer;
Graphical described doping semiconductor layer and described semiconductor layer so that described doping semiconductor layer and semiconductor layer at least one pleurapophysis of frontal plane of projection for described grid;
With described doping semiconductor layer is mask, and the described light-shielding material layers of etching is with the described semiconductor layer of shield portions;
Form one source pole, be electrically connected the described semiconductor layer of part of described raceway groove one side; And
Form a drain electrode, be electrically connected the described semiconductor layer of part of this raceway groove opposite side, wherein said drain electrode is at the frontal plane of projection described gate overlap of getting along well.
11. the method for making of the tft array substrate of LCD as claimed in claim 10 is characterized in that, form described light-shielding material layers before, also comprise forming a photoresist layer on described gate dielectric.
12. the method for making of the tft array substrate of LCD as claimed in claim 11 is characterized in that, the described light-shielding material layers that removes described grid top comprises the following steps:
With described grid is mask, from the described photoresist layer of the back-exposure of described substrate; And
Remove the described photoresist layer that is not exposed, peel off the described light-shielding material layers on the described photoresist layer that is not exposed simultaneously.
13. the method for making of the tft array substrate of LCD as claimed in claim 12 is characterized in that, described photoresist layer is negative photoresistance, and to remove the described photoresist layer that is not exposed be a development step.
14. a display panels is characterized in that comprising:
One first substrate;
One second substrate is with respect to this first substrate;
One thin film transistor (TFT) is arranged on described first substrate, and this thin film transistor (TFT) comprises:
One grid is positioned on described first substrate;
One gate dielectric covers this substrate and described grid;
Semi-conductor layer is positioned on the described gate dielectric, and this semiconductor layer comprises a raceway groove;
One light shield layer is arranged in described semiconductor layer;
One source pole is electrically connected the part semiconductor layer of described raceway groove one side;
One drain electrode is electrically connected the part semiconductor layer of described raceway groove opposite side, and this drain electrode is at frontal plane of projection this gate overlap of getting along well; And
One liquid crystal layer is sandwiched between described first substrate and second substrate.
15. display panels as claimed in claim 14 is characterized in that, described light shield layer is in abutting connection with described gate dielectric, and this light shield layer covers the zone of described semiconductor layer beyond frontal plane of projection and described gate overlap.
16. display panels as claimed in claim 14 is characterized in that, for described grid, and described drain electrode is electrically connected the part of the outstanding grid of this semiconductor layer to described semiconductor layer at frontal plane of projection one pleurapophysis.
17. display panels as claimed in claim 14 is characterized in that,
Described source electrode is half arc, and around described drain electrode, and both are at a distance of a constant spacing;
Described semiconductor layer is positioned at described source electrode and drain electrode below, and its subregion is overlapping in frontal plane of projection and described source electrode, drain electrode; And
The semiconductor layer that is positioned between source electrode and drain electrode is the described raceway groove of described thin film transistor (TFT).
18. display panels as claimed in claim 14 is characterized in that,
Described drain electrode is the L type;
Described source electrode is an inverted L shape, and this source electrode and the fixed interval (FI) apart that drains;
Described semiconductor layer is positioned at described source electrode and drain electrode below, and its subregion is overlapping in frontal plane of projection and described source electrode, drain electrode; And
The semiconductor layer that is positioned between source electrode and drain electrode is the described raceway groove of described thin film transistor (TFT).
19. display panels as claimed in claim 14 is characterized in that,
Described drain electrode is the square type;
Described source electrode is for colluding type, and the part of this source electrode and drain electrode are at a distance of a fixed interval (FI);
Described semiconductor layer is positioned at described source electrode and drain electrode below, and its subregion is overlapping in frontal plane of projection and the described source electrode of part, drain electrode; And
The semiconductor layer that is positioned between source electrode and drain electrode is the described raceway groove of described thin film transistor (TFT).
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CN101872773A (en) * | 2010-06-28 | 2010-10-27 | 信利半导体有限公司 | Thin-film transistor array substrate, display and manufacturing method thereof |
CN103035734A (en) | 2011-10-07 | 2013-04-10 | 元太科技工业股份有限公司 | Metal oxide thin film transistor |
CN106483724A (en) * | 2015-08-28 | 2017-03-08 | 群创光电股份有限公司 | Display device |
CN106449656A (en) * | 2016-10-26 | 2017-02-22 | 京东方科技集团股份有限公司 | Array substrate and manufacturing method thereof and display panel and display device |
CN109671723A (en) * | 2018-12-20 | 2019-04-23 | 深圳市华星光电半导体显示技术有限公司 | A kind of tft array substrate |
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JPH0562996A (en) * | 1991-03-06 | 1993-03-12 | Fuji Xerox Co Ltd | Manufacture of thin film transistor |
US6043113A (en) * | 1995-07-31 | 2000-03-28 | 1294339 Ontario, Inc. | Method of forming self-aligned thin film transistor |
JP2000124463A (en) * | 1998-10-21 | 2000-04-28 | Nec Corp | Thin film transistor element and its manufacture |
US6509591B2 (en) * | 2001-01-20 | 2003-01-21 | Au Optronics Corp. | Thin film transistor with photoconductive material |
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JPH0562996A (en) * | 1991-03-06 | 1993-03-12 | Fuji Xerox Co Ltd | Manufacture of thin film transistor |
US6043113A (en) * | 1995-07-31 | 2000-03-28 | 1294339 Ontario, Inc. | Method of forming self-aligned thin film transistor |
JP2000124463A (en) * | 1998-10-21 | 2000-04-28 | Nec Corp | Thin film transistor element and its manufacture |
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