CN101414620B

CN101414620B - Electronic device, thin-film transistor structure, and flat panel display having the same

Info

Publication number: CN101414620B
Application number: CN2008101755624A
Authority: CN
Inventors: 金恩雅; 李正鲁; 李树美; 申奉周; 李美真
Original assignee: Samsung Mobile Display Co Ltd
Current assignee: Samsung Display Co Ltd
Priority date: 2004-06-30
Filing date: 2005-06-30
Publication date: 2012-08-29
Anticipated expiration: 2025-06-30
Also published as: KR20060001344A; CN1716603B; CN101414620A; KR100563067B1; CN1716603A

Abstract

The invention relates to an electron device, a thin film transistor structure and a flat panel display having the same. The invention provides the electronic device configured to prevent or reduce electrostatic discharge from causing a pixel to malfunction. An electronic device manufactured according to the principles of the invention may include multiple conductive layers that cross but do not contact each other, wherein at least one of the conductive layers includes a width change part having a width that changes in a length direction of the at least one of the conductive layers, and a tab connected to at least one of the conductive layers at a region thereof that does not cross a neighboring conductive layer. Alternatively, the width change part may have a width that continuously varies along a length of the at least one conductive layer and may also have obtuse corner edges. The invention also provides a flat organic electroluminescent display (OELD) or LCD display device that includes such an electronic device.

Description

Electronic device, thin-film transistor structure and flat-panel monitor with this structure

The application be to the applying date be that June 30, application number in 2005 are 200510080518.1, denomination of invention divides an application for the application for a patent for invention of " electronic device, thin-film transistor structure and the flat-panel monitor with this structure ".

Cross reference with related application

The application requires on June 30th, 2004 in the korean patent application 10-2004-0050445 of Korea S Department of Intellectual Property application and the priority of 10-2004-0050446, at this it openly all is incorporated herein by reference.

Technical field

The present invention relates generally to the electronic device and the flat panel display equipment with this device like thin-film transistor (TFT).Yet the present invention is specifically related to wherein avoid or reduced the electronic device and the flat panel display equipment with this electronic device of the electrostatic breakdown that is caused by static.

Background technology

There is multiple display device can be used for display image.Recently, multiple flat panel display equipment has substituted the cathode ray tube (CRT) display.Flat panel display equipment can be divided into emission type and non-emission type according to the emission type of using.The emission type display device comprises plane CRT display device, plasma display panel apparatus, vacuum fluorescence display device, field-emission display device and organic/inorganic electroluminescence display device, but not the emission type display device comprises liquid crystal display.Planar transmit type organic electro-luminescence display device (OELD) is owing to be emission type, and do not comprise luminaire for example backlight and can under low-power consumption and high efficiency, work, so receives much concern.Advantages such as OELD equipment has that operating voltage is low, in light weight, slim body, the visual angle is wide and the video response time is fast.

The conventional electroluminescence cell of OELD equipment be included in first electrode (anode), second electrode (negative electrode) that forms with cascade type on the substrate and be inserted in first electrode and second electrode between organic luminous layer (film).In when work, OELD equipment has the light of specific wavelength through the energy emission that is produced by exciton, and exciton is by in organic film, combining again to form through anode and negative electrode injected electrons and hole.Electron transfer layer (ETL) can be arranged between negative electrode and the organic luminous layer.Similarly, hole transmission layer (HTL) can be arranged between anode and the organic luminous layer.And, hole injection layer (HIL) can be set between anode and HTL.In addition, electron injecting layer (EIL) can be arranged between negative electrode and the ETL.

Passive matrix (PM) OELD equipment can use the hand drive method, and active-matrix (AM) type can use the activation driving method.In PM OELD equipment, anode arranges that by row negative electrode is arranged in a row.Horizontal drive circuit provides sweep signal to negative electrode, and column drive circuit provides data-signal to arrive each pixel.On the other hand, AM OELD equipment uses thin-film transistor (TFT) control to be input to the signal of pixel.Because the use of TFT makes AM OELD can promptly handle a large amount of signals, so AMOELD is widely used in the execution excitation.

The shortcoming of conventional AM OELD equipment is to make or during the equipment of use, because the generation of static and/or be released in the pixel that the viewing area may produce one or more mistakes.

Figure 1A is the plane photo figure of conventional OELD equipment, and wherein the pixel with mistake is shown as bright spot.Figure 1B is the enlarged drawing that is designated as the normal pixel of A among Figure 1A, and Fig. 1 C is the enlarged drawing that is designated as the erroneous pixel of B among Figure 1A.Figure 1B and Fig. 1 C are the bottom view of the conventional OELD equipment of Figure 1A.The sandwich construction that bottom view sees through substrate obtains with different electronics and electroluminescent cell mounted thereto.Therefore, among Figure 1B and Fig. 1 C,

gate line

3a and 3b appear on the conductive layer 5.

In Figure 1B and Fig. 1 C; Each

pixel

1a and 1b comprise electroluminescence cell, gate electrode (2b of the 2a of Figure 1B and Fig. 1 C) and light-emitting film transistor (Mb of the Ma of Figure 1B and Fig. 1 C), and the light-emitting film transistor sends the signal of telecommunication from the drive TFT (not shown) to pixel.The source electrode of luminous TFT Ma and Mb is electrically connected on the drive TFT (not shown) via conductive layer 5.

Fig. 1 D is the part amplification view that is designated as B ' among Fig. 1 C.Referring to Fig. 1 D, conductive layer 5 can extend through other conductive layer.For example, in the bottom view that Fig. 1 D amplifies, show conductive layer 5 and pass gate line 3a/3b.In the figure of example, gate line 3a/3b appears on the conductive layer 5.In the work, gate line 3a/3b plays scan line and/or scan line extension apparatus, is used for to thin-film transistor the signal of telecommunication being provided.

In order to satisfy design specification, the width of each gate line 3a/3b maybe be along its length variations.For example, in the conventional design shown in Figure 1B, Fig. 1 C and Fig. 1 D, the width of each gate line 3a/3b changes in the part of intersecting with conductive layer 5.Shown in Fig. 1 D, gate line 3b wide portions can be that width changes part A _w, the coupling part that gate line 3a/3b is narrower can be cross unit A _cWidth changes part A _wWith cross unit A _cCan and be positioned at separately within the border with conductive layer 5 insulation.Because electric current trends towards the point discharge at conductor,, electrostatic discharge (ESD) changes part A so trending towards occurring in the width shown in Fig. 1 D _wAngle part A _dIn most of the cases, ESD damages corresponding pixel 1a/1b, causes its excessively luminous (for example, bright spot of appearance such as the bright spot B that shows among Figure 1A).Because static concentrates on cross section, so be easy to induce such ESD, therefore, if the insulating barrier that inserts between the conductive layer is damaged, the possibility that produces short circuit between the conductive layer of intersection will increase.Described like Figure 1B and Fig. 1 C, even import pixel 1a and the pixel 1b in Fig. 1 C of identical current signal to Figure 1B, the pixel 1b among Fig. 1 C also can make mistakes, and produces the bright spot that bigger brightness is arranged than normal pixel among Figure 1B.Because the short circuit current between different conductive layer 3b and the conductive layer 5 causes and one different current signals that use more than expectation, so bigger brightness can occur.This undesirable ESD may reduce the picture quality of plane OELD, and plane OELD in whole viewing area the exigent uniformity.

Summary of the invention

The present invention provides a kind of electronic device and a kind of TFT structure, wherein reduces or has avoided the generation of the erroneous pixel that the electrostatic breakdown of conductive layer causes, and a kind of planar transmit type ORGANIC ELECTROLUMINESCENCE DISPLAYS (OELD) equipment with this structure is provided.

One aspect of the present invention provides a kind of electronic device, comprising: first conductive layer; With second conductive layer that intersects with said first conductive layer; Wherein said first conductive layer does not contact said second conductive layer; Wherein said first conductive layer comprises the change width part in the zone that said first conductive layer and said second conductive layer intersect; The width of this change width part changes along the length direction of said first conductive layer; The width of wherein said second conductive layer for constant, and wherein connects angle between 2 line segment on the same plane of the outer lines of change width part and the line segment parallel with the length direction of said first conductive layer less than 90 ° in the zone that said first conductive layer and said second conductive layer intersect.

One aspect of the present invention provides a kind of TFT structure, comprising: first conductive layer; With second conductive layer that intersects with said first conductive layer; Wherein said first conductive layer does not contact said second conductive layer; Wherein said first conductive layer comprises the change width part in the zone that said first conductive layer and said second conductive layer intersect; The width of this change width part changes along the length direction of said first conductive layer; The width of wherein said second conductive layer for constant, and wherein connects angle between 2 line segment on the same plane of the outer lines of change width part and the line segment parallel with the length direction of said first conductive layer less than 90 ° in the zone that said first conductive layer and said second conductive layer intersect.

One aspect of the present invention provides a kind of flat panel display equipment, comprising: substrate; Be formed at the TFT layer on the substrate; With comprise the not only pixel layer of a pixel that is electrically connected to the TFT layer; Wherein the TFT layer comprises first conductive layer and second conductive layer that intersects with said first conductive layer; Wherein said first conductive layer does not contact said second conductive layer; Wherein said first conductive layer comprises the change width part in the zone that said first conductive layer and said second conductive layer intersect; The width of this change width part changes along the length direction of said first conductive layer; The width of wherein said second conductive layer for constant, and wherein connects angle between 2 line segment on the same plane of the outer lines of change width part and the line segment parallel with the length direction of said first conductive layer less than 90 ° in the zone that said first conductive layer and said second conductive layer intersect.

One aspect of the present invention provides a kind of electronic device, comprising: first conductive layer; With second conductive layer that intersects with said first conductive layer; Wherein said first conductive layer does not contact said second conductive layer; Wherein said first conductive layer comprises the part of the area of section along the length direction variation of said first conductive layer; This part is in the zone that said first conductive layer and said second conductive layer intersect; The width of wherein said second conductive layer for constant, and wherein connects angle between 2 line segment on the same plane of the outer lines of the part that the area of section changes and the line segment parallel with the length direction of said first conductive layer less than 90 ° in the zone that said first conductive layer and said second conductive layer intersect.

One aspect of the present invention provides a kind of TFT structure, comprising: first conductive layer; With second conductive layer that intersects with said first conductive layer; Wherein said first conductive layer does not contact said second conductive layer; Wherein said first conductive layer comprises the part of the area of section along the length direction variation of said first conductive layer; This part is in the zone that said first conductive layer and said second conductive layer intersect; The width of wherein said second conductive layer for constant, and wherein connects angle between 2 line segment on the same plane of the outer lines of the part that the area of section changes and the line segment parallel with the length direction of said first conductive layer less than 90 ° in the zone that said first conductive layer and said second conductive layer intersect.

One aspect of the present invention provides a kind of flat panel display equipment, comprising: substrate; Be formed at the TFT layer on the substrate; With comprise the pixel layer that is electrically connected to the TFT layer more than a pixel; Wherein the TFT layer comprises first conductive layer and second conductive layer that intersects with said first conductive layer; Wherein said first conductive layer does not contact said second conductive layer; Wherein said first conductive layer comprises the part of the area of section along the length direction variation of said first conductive layer; This part is in the zone that said first conductive layer and said second conductive layer intersect; The width of wherein said second conductive layer for constant, and wherein connects angle between 2 line segment on the same plane of the outer lines of the part that the area of section changes and the line segment parallel with the length direction of said first conductive layer less than 90 ° in the zone that said first conductive layer and said second conductive layer intersect.

One aspect of the present invention provides a kind of electronic device, comprises intersected with each other but discontiguous a plurality of conductive layer.Wherein at least one conductive layer comprises a change width part, and the width of change width part changes along the length direction of at least one conductive layer.Electronic device further is included in the lug plate that is connected at least one conductive layer or adjacent conductive layer away from the zone of conductive layer overlapping region.

The present invention provides a kind of TFT structure on the other hand, comprises intersected with each other but discontiguous a plurality of conductive layer.Wherein at least one conductive layer comprises a change width part, and the width of change width part changes along the length direction of at least one conductive layer.The TFT structure further is included in the lug plate that is connected at least one conductive layer or adjacent conductive layer away from the zone of conductive layer overlapping region.

The present invention provides a kind of flat panel display equipment to comprise substrate on the other hand, is formed on TFT layer on the substrate, is formed at least one insulating barrier and pixel layer on the TFT layer, this pixel layer comprise through the through hole that is formed on insulating barrier be electrically connected to the TFT layer more than one pixel.The TFT layer comprises intersected with each other but discontiguous a plurality of conductive layer.At least one conductive layer comprises a change width part, and the width of change width part changes along the length direction of at least one conductive layer.Flat panel display equipment further is included in the lug plate that is connected at least one conductive layer or adjacent conductive layer away from the zone of conductive layer overlapping region.

The present invention provides a kind of electronic device on the other hand, comprises intersected with each other but discontiguous a plurality of conductive layer.At least one conductive layer comprises a change width part, and the width of change width part changes along the length direction of at least one conductive layer.Electronic device further comprise between two line segments less than 90 ° angle, line segment connects 2 points on the same plane of the outer lines that is positioned at the change width part, another line segment is parallel with the length direction of at least one conductive layer.

The present invention provides a kind of TFT structure on the other hand, comprises intersected with each other but discontiguous a plurality of conductive layer.At least one conductive layer comprises a change width part, and the wide section length direction along at least one conductive layer of change width part changes.The TFT structure further comprise between two line segments less than 90 ° angle, line segment connects 2 points on the same plane of the outer lines that is positioned at the change width part, another line segment is parallel with the length direction of at least one conductive layer.

The present invention provides a kind of flat-panel display devices on the other hand; Comprise substrate, be formed at TFT layer on the substrate, at least one is formed at insulating barrier and pixel layer on the TFT layer, this pixel layer comprise through be formed on through hole on the insulating barrier be electrically connected to the TFT layer more than a pixel.The TFT layer comprises intersected with each other but discontiguous a plurality of conductive layer.At least one conductive layer comprises a change width part, and the width of change width part changes along the length direction of at least one conductive layer.The TFT layer may further include between two line segments less than 90 ° angle, line segment connects 2 points on the same plane of the outer lines that is positioned at the change width part, another line segment is parallel with the length direction of at least one conductive layer.

The present invention provides a kind of electronic device on the other hand, comprises intersected with each other but discontiguous a plurality of conductive layer, and wherein at least one conductive layer comprises the part of the area of section along the length direction variation of at least one conductive layer.Electronic device may further include the lug plate that is connected at least one conductive layer or adjacent conductive layer in the zone away from the conductive layer overlapping region.

The present invention provides a kind of TFT structure on the other hand, comprises intersected with each other but discontiguous a plurality of conductive layer, and wherein at least one conductive layer comprises the part of the area of section along the length direction variation of at least one conductive layer.The TFT structure may further include the lug plate that is connected at least one conductive layer or adjacent conductive layer in the zone away from the conductive layer overlapping region.

The present invention provides a kind of flat panel display equipment on the other hand; Comprise substrate, be formed at TFT layer on the substrate, at least one is formed at insulating barrier and pixel layer on the TFT layer, this pixel layer comprise through be formed on through hole on the insulating barrier be electrically connected to the TFT layer more than a pixel.The TFT layer comprises intersected with each other but discontiguous a plurality of conductive layer.At least one conductive layer comprises the part of the area of section along the length direction variation of at least one conductive layer.Flat panel display equipment may further include the lug plate that is connected at least one conductive layer or adjacent conductive layer in the zone away from the conductive layer overlapping region.

The present invention provides a kind of electronic device on the other hand, comprises intersected with each other but discontiguous a plurality of conductive layer, and wherein at least one conductive layer comprises the part of the area of section along the length direction variation of at least one conductive layer.The angle of connection between 2 line segment on the same plane of the outer lines of change width part and the line segment parallel with the length direction of at least one conductive layer is less than 90 °.

The present invention provides a kind of TFT structure on the other hand, comprises intersected with each other but discontiguous a plurality of conductive layer, and wherein at least one conductive layer comprises the part of the area of section along the length direction variation of at least one conductive layer.The angle of connection between 2 line segment on the same plane of the outer lines of change width part and the line segment parallel with the length direction of at least one conductive layer is less than 90 °.

The present invention provides a kind of flat panel display equipment on the other hand; Comprise substrate, be formed at TFT layer on the substrate, at least one is formed at insulating barrier and pixel layer on the TFT layer, this pixel layer comprise through be formed on through hole on the insulating barrier be electrically connected to the TFT layer more than a pixel.The TFT layer comprises intersected with each other but discontiguous a plurality of conductive layer.At least one conductive layer comprises the part of the area of section along the length direction variation of at least one conductive layer.The angle of connection between 2 line segment on the same plane of the outer lines of change width part and the line segment parallel with the length direction of at least one conductive layer is less than 90 °.

Description of drawings

Through describing exemplary embodiment in detail with reference to accompanying drawing, above and further feature and advantage of the present invention will be more obvious.

Figure 1A is the photo of the viewing area of conventional organic electro-luminescence display device;

Figure 1B is the part enlarged photograph that is designated as the normal pixel of A among Figure 1A;

Fig. 1 C is the part enlarged photograph that is designated as the erroneous pixel of B among Figure 1A;

Fig. 1 D is the amplification bottom view of a part that is designated as the pixel of B ' among Fig. 1 C;

Fig. 1 E is the cross sectional photograph of a part that is designated as the pixel of B ' among Fig. 1 C;

Fig. 2 A is the floor map of organic electro-luminescence display device according to an embodiment of the invention;

Fig. 2 B is the circuit diagram of pixel that is designated as the OELD equipment of C among Fig. 2 A;

Fig. 2 C is the fragmentary cross-sectional view that is designated as the pixel of C according to an embodiment of the invention among Fig. 2 A;

Fig. 2 D is the partial plan that is presented at the modification embodiment of the part among Fig. 2 C;

Fig. 2 E is the part enlarged photograph of pixel among Fig. 2 C;

Fig. 3 A is the fragmentary cross-sectional view that is designated as the pixel of C in accordance with another embodiment of the present invention among Fig. 2 A;

Fig. 3 B is the enlarged drawing that is designated as the part of D according to an embodiment of the invention among Fig. 3 A;

Fig. 3 C is the part enlarged photograph that is presented at the pixel among Fig. 3 A.

Embodiment

Following reference has shown that wherein the accompanying drawing of exemplary embodiment of the present describes the present invention more fully.

Fig. 2 A is the floor map according to ORGANIC ELECTROLUMINESCENCE DISPLAYS (OELD) equipment of principle manufacturing of the present invention.With reference to Fig. 2 A; Substrate 110 comprises the viewing area of having arranged on it such as the luminaire of organic electro-luminescence display device 200; The hermetic unit 800 of 200 edge sealing-in substrate 110 and hermetic sealing substrate (not shown) along the viewing area, with and go up the terminal region 700 of arranging multiple terminal.Yet the present invention is not limited to this, and it can be embodied as multiple different form.The sealant that for example, can comprise the hermetic unit effect.

Be used to provide power supply can be arranged between viewing area 200 and the hermetic unit 800 to the driving power supply line 300 of viewing area 200.Fig. 2 A shows the example of driving power supply line of the present invention, but the present invention is not limited to this.In order to ensure the uniform luminance of viewing area 200, driving power supply line 300 can center on viewing area 200, to provide uniform driving power to whole viewing area 200.

Driving power supply line 300 can link to each other with driving power supply line 310, and driving power supply line 310 can be crossed over viewing area 200 and arrange, and is electrically connected to the source electrode 170a (shown in Fig. 2 C) that is arranged in below the protective layer 180 (shown in Fig. 2 C).

In addition, outside the border of viewing area 200, can arrange the

drive circuit unit

500 and 600 of vertical and level.Vertical circuit unit 500 can be apply sweep signal to the viewing area 200 scan drive circuit unit, horizontal drive circuit unit 600 can be apply data-signal to the viewing area 200 data drive circuit unit.

Drive circuit unit

500 and 600 vertical and level can be used as external integrated (IC) or glass top chip (COG) the arrangements of cells outside on the seal area border.

Provide electrode supply can be arranged in outside the border of viewing area 200 to the electrode supply supply line 410 of viewing area 200; And be electrically connected to the second electrode lay through the through hole in the insulating barrier that forms between electrode supply supply line 410 and the second electrode lay 430, the second electrode lay is on the top of viewing area 200, to form.

Driving power supply line 300, electrode supply supply line 410 and drive circuit unit 500 vertical and level and 600 comprise terminal 320,420,520 and 620 respectively, and through the lead-in wire be arranged in the seal area border outside terminal region 700 be electrically connected.

Viewing area 200 comprises a plurality of pixels, will describe this with reference to Fig. 2 B and Fig. 2 C below.Fig. 2 B is the circuit diagram of a pixel, and this pixel is arranged in Fig. 2 A, and to be designated as the n row and the m of OELD equipment of the embodiment of the invention of C capable.

Shown in Fig. 2 B, pixel comprises five transistors and two capacitors, and each transistor is described to PMOS TFT, but the present invention is not limited to this.

During use, first sweep signal inputs to viewing area 200 (referring to Fig. 2 A) with second scan line from vertical circuit unit 500 through many first scan lines respectively with second sweep signal.The first sweep signal S [n] and S [n-1] and the second sweep signal E [n] be through the input of first scan line and second scan line, and as the data voltage V of data-signal _{Data [m]}Be input to through data wire and be designated as being in the capable pixel of n row and m of C among Fig. 2 A.

The one TFT M1 will offer Organic Light Emitting Diode (OLED) corresponding to the electric current that is applied to the data voltage of a TFT M1 through the 2nd TFT M2.

N the selection signal S [n] that the 2nd TFT M2 provides in response to first scan line, conversion is applied to the data voltage of data wire.

The 3rd TFT M3 is in response to (n-1) the individual selection signal S [n-1] that is applied to first scan line, and diode connects a TFT M1.

The 4th TFT M4 is that the end of the first capacitor C1 provides fixed voltage in response to (n-1) the individual selection signal S [n-1] that is applied to first scan line.

The 5th TFT M5 is in response to the luminous signal E [n] that is applied to second scan line, and the electric current that a TFTM1 is provided sends OLED to.

The first capacitor C1 keeps time of a part of at least one frame of grid and the voltage between the source electrode of a TFT M1, and the data voltage of the threshold voltage that the second capacitor C2 will be by way of compensation is applied to the grid of a TFT M1.

The TFT layer that comprises present embodiment and the OELD operation of equipment of pixel layer are described below.The TFT layer can comprise the other electron component of at least one TFT and for example capacitor.The TFT layer can be regarded as pixel circuit unit.

As (n-1) individual selection signal S [n-1] when exciting, the 3rd TFT M3 conducting, then; The one TFT M1 that is to say drive thin film transistors, gets into the diode connection status; And because the 5th TFT M5 breaks off, the threshold voltage of a TFT M1 is stored among the second capacitor C2.

If select in response to n to import data voltage after signal S [n] connection in response to (n-1) individual selection signal S [n-1] disconnection and a TFT M1 at the 3rd TFT M3, the calibrated data voltage that will compensate threshold voltage so is applied to the grid of a TFT M1.

Simultaneously, if the 5th TFT M5 in response to n luminous signal E [n] conducting, is sent to OLED through the 5th TFT M5 with current signal so, OLED is luminous, and this current signal is adjusted through the voltage of the grid that is applied to a TFT M1.

Fig. 2 C is the fragmentary cross-sectional view of OELD, and OELD comprises pixel layer R _PWith TFT layer R _T, just electroluminescence cell and pixel layer, pixel layer comprises a TFT M1 and the 5th TFT M5, and a TFT M1 is a drive thin film transistors, and the 5th TFT M5 is the switching thin-film transistor that the signal of telecommunication is provided for pixel layer.

Referring to Fig. 2 C, for example the TFT layer of a TFT M1 is formed on the part of substrate 110.The semiconductor active layer 130 of the one TFT M1 is formed on the part of upper surface of resilient coating 120, and resilient coating 120 is formed on the surface of substrate 110.Semiconductor active layer 130 can be amorphous silicon layer or polysilicon layer.Although do not describe in detail, semiconductor active layer 130 comprises source region and drain region and the channel region that is mixed with P type or N type dopant.Yet, comprise that the thin-film transistor of semiconductor active layer 130 can constitute by different ways.

The gate electrode 150 of the one TFT M1 can be arranged on the part of semiconductor active layer 130.In view of contact with adjacent layer, the surface flatness and the disposal ability of lamination, gate electrode 150 preferably is made up of the material of for example MoW and Al, but is not limited thereto.

Be used for being arranged between the two from the gate insulation layer 140 of semiconductor active layer 130 insulated gate electrodes 150.Intermediate layer 160 as insulating barrier is single or multiple lifts and is formed on gate electrode 150 and the gate insulation layer 140.The source electrode of the one TFT M1 and

drain electrode

170a and 170b are formed on the intermediate layer 160.Source electrode and

drain electrode

170a and 170b can be formed by the metal such as MoW, and heat treatment after forming, so as with semiconductor active layer 130 ohmic contact glossily.

Protective layer 180 is insulating barriers, can be made up of passivation layer and/or levelling blanket, is used to protect and/or smooth lower layer, and is formed on source electrode and drain electrode 170a and the 170b.Such as Fig. 2 C description, protective layer 180 can be an individual layer, by such as SiN _xInorganic material form or for example the organic material of benzocyclobutene or acrylic form, also can be the lamination of multilayer.

The one TFT M1 has been electrically connected to the 5th TFT M5 of switching TFT effect through the extension apparatus 170c of drain electrode 170b.The 5th semiconductor active layer 230 of the 5th TFT M5 is formed on the resilient coating 120, and resilient coating 120 is formed on the surface of substrate 110.The 5th semiconducting insulation layer 230 can with second scan line and/or the insulation of the 5th gate electrode 250, the 5th gate electrode 250 be formed on gate insulation layer 140 above.Intermediate layer 160 and the 5th source/

drain electrode

270a and 270b can be formed on the surface of the 5th gate electrode.The 5th source electrode and

drain electrode

270a and 270b and the 5th semiconductor active layer 230 can be electrically connected through the contact hole that is formed in intermediate layer 160 and the gate insulation layer 140.At least one protective layer 180 that plays the insulating barrier effect can be formed on the 5th source electrode and drain electrode 270a and the 270b, comprises the pixel layer R of first electrode layer 290, electroluminescence cell 292 and the second electrode lay 400 of sequential cascade _PCan be formed on the protective layer 180.

Describe below and form pixel layer R _PMethod.At first, after forming first electrode layer 290, pixel limit layer 291 can be formed on the outer protective layer 180 in pixel open zone 294 above.The electroluminescence cell 292 that comprises luminescent layer can be arranged on the surface of first electrode layer 290 in pixel open zone 294, and the second electrode lay 400 can be formed on the whole surface of composite.

Electroluminescence cell 292 can be made up of low molecule or polymer organic film.If electroluminescence cell 292 is made up of low molecular organic film; HIL, HTL, EML, ETL and EIL can range upon range ofly be single structure or composite construction so; And operable low molecular organic material comprises copper phthalocyanine (CuPc), N; N '-Di (naphthalene-1-yl)-N, N '-diphenyl-benzidine (NPB), or three-oxine aluminium (Alq3).Low molecular organic film can use evaporation to form.

If electroluminescence cell 292 is made up of the polymer organic film, it can comprise HTL and EML so.HTL can be made up of PEDOT, and EML can be by gathering-1,2-ethenylidene phenyl (PPV) and gather fluorenes and form.The polymer organic film can form through the whole bag of tricks, includes but not limited to method for printing screen and ink jet printing method.

The second electrode lay 400 plays negative electrode, and can be deposited on the entire upper surface of electroluminescence cell 292.The second electrode lay 400 is not limited to be deposited on the entire upper surface.It can be by forming like Al/Ca, ITO or Mg-Ag material.The second electrode lay 400 can be formed by the multiple different form of for example multilayer, and may further include that alkali is fluoridized or the alkaline earth fluorinated layer, like the LiF layer.

First scan line and/or scan line extension apparatus 240 (first scan line hereinafter referred to as) can be formed between a TFT M1 and the 5th TFT M5.First scan line 240 can contactlessly pass the extension apparatus 170c of the drain electrode 170b of a TFT M1.Shown in Fig. 2 B, first scan line 240 can be a conductive layer, and (n-1) individual selection signal S [n-1] is sent to third and fourth TFT M3 and the M4 through this conductive layer, and first scan line 240 comprises the change width part A _w, itself since TFT have different design specifications and on the length direction of first scan line width change to some extent.

Just, the partial plan shown in Fig. 2 C, first scan line 240 can form has zone of intersection A _cConductive layer, the A in the zone of intersection _cFirst scan line passes at least but does not contact extension apparatus 170c.First scan line 240 can be arranged in below the extension apparatus 170c that drain electrode 170b extends out.First scan line 240 comprises the change width part A _w, its width is from first width W _cChange to second width W _w, perhaps from second width W _wChange to first width W _cFirst width W _cWith second width W _wDiffer from one another, and width W _cCan compare width W _wWide.The change width part A of first scan line 240 _wAlso can be defined as such part: its area of section changes on the length direction of first scan line 240.

First scan line 240 can comprise a lug plate 241 in the zone that does not intersect with adjacent conductive layer 170c.Because charging concentrates on lug plate 241 rather than change width part A _w, just can avoid because static discharges the change width part A _wThe generation of short circuit current.

The effective width W of lug plate 241 _sEffective length W with lug plate 241 _dRatio can be less than second width W _wWith first width W _cRatio so that static concentrates in the lug plate 241.Just, W _s/ W _d＜W _w/ W _c＜1.Here, first width W _cCan be the measured value of change width part Breadth Maximum, and second width W _wIt can be the measured value of change width part minimum widith.

In the present embodiment, first scan line 240 can be a conductive layer, comprises lug plate 241, and plays gate electrode or gate line.Yet this is an exemplary embodiment of the present invention, and the present invention is not limited to this.

Shown in Fig. 2 C, lug plate 241 can be formed on first scan line 240 (or the extension of first scan line is a conductive layer) that a TFT M1 extends.Yet lug plate 241 can form multiple different form, as long as lug plate 241 does not pass adjacent conductive layer.Like this, the conductive layer that is connected lug plate 241 can be formed on same one deck of source electrode and drain electrode.Lug plate 241 also can extend with the direction with respect to a TFT M1.Alternately, shown in Fig. 2 D, lug plate 241 can be formed on and comprise the change width part A _wConductive layer and/or adjacent conductive layer on.

Fig. 2 E is the plane graph that is presented at the part enlarged photograph of the pixel among Fig. 2 C.In Fig. 2 E, lug plate 241 contact conductive layer districts.For fear of and/or reduce static and discharge, the zone of lug plate 241 contact conductive layer is away from the conductive layer overlapping areas.Because discharging, static do not occur in the change width part A _wBut occurring in not the lug plate 241 that intersects with conductive layer, the electrostatic breakdown to the conductive layer of TFT layer can avoided or reduce to this structure.Like this, the conductive layer of overlapping and/or the short circuit current fault between the pixel just can be avoided or reduced.

Fig. 3 A, 3B and 3C show the pixel of the OELD equipment of making according to principle of the present invention.First scan line and/or scan line extension apparatus 240 (first scan line hereinafter referred to as) are formed between a TFT M1 and the 5th TFT M5.First scan line 240 passes but does not contact the extension apparatus 170c of the drain electrode 170b of a TFT M1.Shown in Fig. 2 B, first scan line 240 is that (n-1) individual selection signal S [n-1] is transmitted conductive layer so far, transmits (n-1) individual sweep signal S [n-1] and refers to third and fourth TFT M3 and the M4.First scan line 240 can comprise the change width part A _w, its width changes on the length direction of first scan line 240.Just, shown in the partial plan shown in Fig. 3 A, first scan line 240 can form has zone of intersection A _cConductive layer, the zone of intersection is passed but is not contacted at least the part of the extension apparatus 170c that extends out from drain electrode 170b.First scan line can be arranged in below the extension apparatus 170c.First scan line 240 can be included in the change width part A on the length direction of first scan line 240 _w, and the change width part A _wWidth can be from W _cTo W _wChange continuously.

Shown in Fig. 3 A,, be designated as the P1 of reference number and the point that is positioned at the adjacent conductive layer zone of intersection of P2 (referring to Fig. 2 B) and be easy to damaged by static release if corresponding width change section branch comprises the tip.Yet, in an embodiment of the present invention, the change width part A _wDo not comprise any sharp-pointed comer edge that possibly cause static to discharge.On the contrary, change width part A _wWidth change continuously along first scan line 240, to such an extent as to change width partly comprise crooked be not the comer edge at 90 ° of angles.Therefore, cause that the electric charge that static discharges does not concentrate on the change width part A _wThereby, avoid or reduced electrostatic breakdown pixel.

The change width part A _wThe turning preferably can have the obtuse angle and be circular.Fig. 3 B is the enlarged drawing of part D among Fig. 3 A.Referring to Fig. 3 B, angle θ is formed at line segment O ₁O ₂With line segment O ₁O ₃Between, line segment O ₁O ₂From an O ₁Extend to an O ₂, these two points are positioned at intersected with each other but discontiguous change width part A _wSame plane on, line segment O ₁O ₃From an O ₁Extend to an O ₃, some O ₃Be positioned on the length direction of first scan line 240.For fear of the edge of charge concentration at first scan line 240, the angle θ between two line segments can be less than 45 °.

Fig. 3 C is the part enlarged photograph that is presented at pixel among Fig. 3 A.Referring to Fig. 3 C, because the change width part A of passing the conductive layer of at least one adjacent conductive layer _wWidth because obtuse angle and smooth change, can avoid therefore can avoiding the generation of erroneous pixel to the electrostatic breakdown of the conductive layer of thin-film transistor and/or the short circuit current between the adjacent conductive layer.

The above embodiments are exemplary, and the present invention is not limited thereto.Just, the foregoing description has been described about being formed at the conductive layer of the extension between drain electrode and the scan line, but the present invention goes for other conductive layer.Simultaneously, the invention describes TFT structure with five last grid type transistors and two capacitors and the OELD equipment that comprise the TFT structure.Yet the present invention can carry out the modification of various ways, is connected on the lug plate 241 in the conductive layer area of not passing adjacent conductive layer as long as have the conductive layer of change width part.In addition, connecting the line segment and the angle that is parallel between the line segment of the direction that conductive layer with change width part extends at the turning of change width part can be less than 90 °.Principle of the present invention can be applied to OELD equipment and LCD equipment regardless of transistorized type.Further, the present invention also goes for having a plurality of intersected with each other but electronic devices of discontiguous conductive layer.

The present invention can provide following some or whole advantages.At first; The conductive layer that is included in the lug plate 241 in the conductive layer district of not passing adjacent conductive layer and at least one TFT, uses wiring chip of the present invention can be avoided and/or reduce the static that when making and/or use TFT, produces the static that is formed at the insulating barrier between the conductive layer is discharged damage.

Secondly; In the flat panel display equipment of the OELD that for example comprises a TFT layer; Wherein the TFT layer comprises a plurality of conductive layers, and lug plate 241 is to be connected to the conductive layer district of not passing adjacent conductive layer, and lug plate 241 is connected at least one conductive layer with change width part; Perhaps be connected to adjacent conductive layer, this adjacent conductive layer can avoid being discharged by the static that lug plate 241 provides the generation of caused erroneous pixel.Such structure can improve picture quality.

The 3rd, the conductive layer of a TFT can comprise the part that does not contact adjacent conductive layer of passing wherein but comprise not only.Conductive layer can comprise the change width part, forms this part in order to the abundant overlapping zone of intersection.The width of change width part can change continuously, so that the turning of change width part is the obtuse angle.Because there is not sharp-pointed comer edge to occur concentrating electrostatic charge, thus to the insulating barrier that forms between the conductive layer because the damage that static discharges can be avoided and/or reduced, therefore avoid product bug.

The 4th, in the flat panel display equipment of the OELD that for example comprises a TFT layer, have the conductive layer that intersects but do not contact the zone of adjacent conductive layer and can comprise a change width part.Therefore, through partly avoid the possibility that concentrating of static can be reduced or the debug pixel produces in change width, the generation of erroneous pixel is owing in production or operation TFT process, produce static.This can be through width that changes the change width part continuously and round the obtaining of turning change that makes wherein.The generation of electrostatic charge in the change width part can avoided or reduce to such structure, thereby improved picture quality.

Above reference exemplary embodiment wherein illustrates and has described the present invention, those skilled in the art should understand that the various variations on form and the details do not break away from the spirit and scope of the present invention that following claim limits.

Claims

1. electronic device comprises:

First conductive layer; With

Second conductive layer that intersects with said first conductive layer,

Wherein said first conductive layer does not contact said second conductive layer,

Wherein said first conductive layer comprises the change width part in the zone that said first conductive layer and said second conductive layer intersect, the width of this change width part changes along the length direction of said first conductive layer,

The width of wherein said second conductive layer is constant in the zone that said first conductive layer and said second conductive layer intersect, and

Wherein connect angle between 2 line segment on the same plane of the outer lines of said change width part and the line segment parallel less than 90 ° with the length direction of said first conductive layer; The width of this change width part changes along the length direction of said first conductive layer continuously, and the turning of said change width part is the obtuse angle and is circular.

2. electronic device according to claim 1, the gate electrode that wherein said first conductive layer is TFT or the extension of TFT gate electrode.

3. electronic device according to claim 1, source electrode or drain electrode that wherein said first conductive layer is TFT, or the source electrode of TFT or the extension of drain electrode.

4. TFT structure comprises:

First conductive layer; With

Second conductive layer that intersects with said first conductive layer,

5. TFT structure according to claim 4, wherein said first conductive layer are the extensions of gate electrode or the gate electrode of TFT.

6. TFT structure according to claim 4, source electrode or drain electrode that wherein said first conductive layer is TFT, or the source electrode of TFT or the extension of drain electrode.

7. flat panel display equipment comprises:

Substrate;

Be formed at the TFT layer on the substrate; With

Comprise the not only pixel layer of a pixel that is electrically connected to the TFT layer,

Wherein the TFT layer comprises first conductive layer and second conductive layer that intersects with said first conductive layer,

Wherein connect angle between 2 line segment on the same plane of the outer lines of change width part and the line segment parallel less than 90 ° with the length direction of said first conductive layer; The width of this change width part changes along the length direction of said first conductive layer continuously, and the turning of said change width part is the obtuse angle and is circular.

8. flat panel display equipment according to claim 7, wherein said first conductive layer is a gate electrode.

9. flat panel display equipment according to claim 7, wherein said first conductive layer is source electrode or drain electrode.

10. flat panel display equipment according to claim 7, wherein pixel layer comprises:

First electrode;

Be formed at the electroluminescence cell on first electrode; With

Be formed at second electrode on the electroluminescence cell.

11. flat panel display equipment according to claim 7 further comprises at least one insulating barrier that is formed on the TFT layer, wherein the pixel of pixel layer is electrically connected to the TFT layer through the contact hole that is formed at least one insulating barrier.

12. an electronic device comprises:

First conductive layer; With

Second conductive layer that intersects with said first conductive layer,

Wherein said first conductive layer comprises the part that the area of section changes along the length direction of said first conductive layer, this part in the zone that said first conductive layer and said second conductive layer intersect,

Wherein connect angle between 2 line segment on the same plane of the outer lines of the said area of section and the line segment parallel less than 90 ° with the length direction of said first conductive layer; The width of this area of section changes along the length direction of said first conductive layer continuously, and the turning of the said area of section is the obtuse angle and is circular.

13. electronic device according to claim 12, the gate electrode that wherein said first conductive layer is TFT or the extension of TFT gate electrode.

14. electronic device according to claim 12, source electrode or drain electrode that wherein said first conductive layer is TFT, or the extension of TFT source electrode or drain electrode.

15. a TFT structure comprises:

First conductive layer; With

Second conductive layer that intersects with said first conductive layer,

16. TFT structure according to claim 15, the gate electrode that wherein said first conductive layer is TFT or the extension of TFT gate electrode.

17. TFT structure according to claim 15, source electrode or drain electrode that wherein said first conductive layer is TFT, or the extension of TFT source electrode or drain electrode.

18. a flat panel display equipment comprises:

Substrate;

Be formed at the TFT layer on the substrate; With

Comprise the pixel layer that is electrically connected to the TFT layer more than a pixel,

Wherein said first conductive layer does not contact said second conductive layer, and wherein said first conductive layer comprises the part that the area of section changes along the length direction of said first conductive layer, this part in the zone that said first conductive layer and said second conductive layer intersect,

19. flat panel display equipment according to claim 18, wherein said first conductive layer is a gate electrode.

20. flat panel display equipment according to claim 18, wherein said first conductive layer is source electrode or drain electrode.

21. flat panel display equipment according to claim 18, wherein pixel layer comprises:

First electrode;

Be formed at the electroluminescence cell on first electrode; With

Be formed at second electrode on the electroluminescence cell.

22. flat panel display equipment according to claim 18 further comprises at least one insulating barrier that is formed on the TFT layer, wherein the pixel of pixel layer is electrically connected to the TFT layer through the contact hole that is formed at least one insulating barrier.