JP4465954B2 - Method for manufacturing display device having transparent conductive film - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for patterning a transparent conductive film used for a transparent electrode on a multilayer thin film such as a plasma display, a liquid crystal display, or an organic EL display.
[0002]
[Prior art]
Transparent conductive films are currently used as transparent electrodes for array substrates such as plasma displays and liquid crystal displays, which are the mainstream of flat displays. In the field of electronic paper, which is being developed as a future display device, it is widely used as a transparent electrode, and its application is expanding. And the competition for higher definition and lower cost of displays has become more intense in recent years, and higher quality and higher productivity are required even at manufacturing sites.
[0003]
The transparent conductive film is usually patterned into a desired shape by photolithography. FIG. 11 shows a cross-sectional configuration diagram of each step of the photolithography step. For example, a transparent conductive film 3 made of an indium tin oxides (ITO) film or a ZnO film is vacuum-deposited on a substrate 101 such as glass, plastic or silicon wafer, and a resist layer 103 is formed thereon. The thin film (FIG. 11A) is irradiated with light through a photomask 104 having a predetermined pattern to expose the resist layer 103 (FIG. 11B). Then, the photomask pattern is transferred to the resist layer 103 by development and post-baking (FIG. 11C), and the portion of the transparent conductive film 102 not covered with the resist is removed by etching (FIG. 11D). A desired pattern is obtained by removing the residual resist layer 103 (FIG. 11E).
[0004]
However, the photolithography process described above requires a large apparatus such as a coater / developer, which hinders reduction in manufacturing costs. In addition, since a large amount of chemical solution such as a developer is used, there is a problem in terms of environmental conservation. Furthermore, for example, in a reflection / transmission combined type low-temperature polysilicon liquid crystal display, an ITO film is used as a transmission part of a pixel electrode of a substrate provided with a TFT (thin film transistor), and an Al film is used as a reflection film. Even if the patterning has the same pattern shape, the resist and the developer are different, so that the photolithography process is required twice. In order to simplify the manufacturing process, a technique for directly processing a transparent conductive film and a metal film using laser light has been proposed (see, for example, Patent Document 1).
[0005]
[Patent Document 1]
JP 2000-31463 A (page 3-4)
[0006]
[Problems to be solved by the invention]
However, for example, when an ITO film formed on a glass substrate is processed with a high-energy laser beam such as a YAG laser, the glass substrate is damaged due to thermal effects. And the problem that the splash of the removed ITO film adheres to a process part periphery etc. generate | occur | produces. In addition, there is a method of processing a glass substrate in a vacuum chamber in order to prevent the ITO film splashes from re-adhering to the surface of the glass substrate. However, as the glass substrate becomes larger, the vacuum chamber is necessarily larger. Therefore, the time required for evacuation before pattern processing and opening to the atmosphere for replacing the glass substrate becomes long, and there is a problem in terms of throughput.
[0007]
Furthermore, the lower layer of the transparent conductive film may have a multilayer structure with different laser light absorption rates depending on the device, but depending on the optical characteristics of the resin layer, the resin layer may be damaged by the laser light irradiation. . For example, a color filter substrate of a low-temperature polysilicon liquid crystal display is formed by an overcoat resin layer applied by a spin coater or the like on a black matrix formed by a pigment dispersion method, and further formed thereon by a sputtering method. Although it has a multilayer structure composed of transparent conductive film such as ITO film, the black matrix in which pigment is dispersed in resin has a high laser light absorption rate, and when the transparent conductive film is irradiated with laser light, the transparent conductive film There is a problem that the black matrix may be damaged by the transmitted laser beam.
[0008]
Moreover, although the irradiation energy density of the laser light may be varied by changing the angle of the attenuator depending on the area of the substrate of the device, there is a problem that it cannot be reproduced with high accuracy. For example, since the absorption rate of the laser beam is different between the above-described color filter substrate where the black matrix is present and not present, it is necessary to vary the irradiation energy density of the laser beam, but the method of using the attenuator reproduces the irradiation energy. There was a problem that it was not good.
[0009]
In view of such a point, an object of the present invention is to provide a transparent conductive film patterning method capable of realizing a high-quality multilayer thin film while realizing high productivity by omitting an extra photolithography process.
[0010]
[Means for Solving the Problems]
  Of the present inventionFirstManufacturing method of display device having transparent conductive filmLaw isA transparent resin layer is formed on the substrate, and the transparent resin layerTransparentResin layerThanLinear expansion coefficientIs smallmaterialConsist ofA transparent conductive film was formed and patterned on the surface of the transparent conductive film through a mask.Of a given energy densityLaser light is irradiated by a projection optical system, and the laser light irradiated portion of the transparent conductive film isIt is also formed after the laser beam irradiationAboveTransparentPatterning is performed by removing from the resin layer and removing it.
[0011]
  SuchFirstAccording to the present invention, the film was formed on the transparent resin layer., Made of a material having a smaller linear expansion coefficient than the transparent resin layerFor transparent conductive film,Patterned through the maskOf a given energy densityBy irradiating laser light, ablation of the transparent conductive film,Thermally expandedThe transparent conductive film is formed by utilizing the distortion of the interface due to the difference in linear expansion coefficient between the transparent conductive film and the transparent resin layer and the vaporization due to the ablation of the surface of the transparent resin layer.Transparent formed even after laser light irradiationResin layerUpThe transparent conductive film can be selectively patterned by removing it explosively.
[0012]
  Of the present inventionSecondManufacturing method of display device having transparent conductive filmLaw isA first resin layer made of a resin containing a pigment is formed on the substrate, a second resin layer made of a transparent resin is formed on the first resin layer, and the second resin layer is formed on the second resin layer. ConcernedSecondResin layerThanLinear expansion coefficientIs smallA transparent conductive film made of a material was formed and patterned on the surface of the transparent conductive film through a mask.Of a given energy densityIrradiating a laser beam with a projection optical system, interposing the second resin layer between the first resin layer and the transparent conductive film having a higher absorption rate of the laser beam than the second resin layer,From above the second resin layer formed even after the laser light irradiation,Patterning is performed by removing and removing the laser light irradiated portion of the transparent conductive film.
[0013]
  SuchSecondAccording to the present invention, the first resin layer and the second resin layer were further formed thereon.Made of a material having a smaller linear expansion coefficient than the second resin layerFor transparent conductive film,Patterned through the maskOf a given energy densityBy irradiating laser light, ablation of the transparent conductive film,Thermally expandedUsing the distortion of the interface due to the difference in linear expansion coefficient between the transparent conductive film and the second resin layer and the vaporization due to the ablation of the second resin layer surface, TransparentBright conductive filmIt is formed even after laser light irradiationSecond resin layerUpFromExplosivelyThe transparent conductive film can be patterned without detaching and removing and damaging the first resin layer.
[0014]
  Also aboveSecondIn the present invention, in a partial region on the substrateSaidForming a first resin layer on the substrate including the first resin layer;SaidA second resin layer was formed and formed on the second resin layerSaidThe transparent conductive film is irradiated with the laser light through the mask whose transmittance varies stepwise by changing the film thickness, and the region where the first resin layer is formed by the mask and other regions The patterning is performed by changing the irradiation energy density to the transparent conductive film.
[0015]
  According to the present invention,By changing the mask film thickness step by step to adjust the laser beam transmittance and changing the irradiation energy density of the laser beam irradiated to the irradiated surface, A region having one resin layer and a region having no resin layer can be simultaneously patterned with laser beams having different irradiation energy densities.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an example of an embodiment of a patterning method for a transparent conductive film of the present invention will be described with reference to the drawings.
[0025]
FIG. 3 shows a configuration diagram of an example of a laser patterning device used in the patterning method of the transparent conductive film of this example. Reference numeral 7 denotes a laser oscillator, and 8 denotes an optical path of laser light emitted from the laser oscillator 7. Further, 9 is an optical system, 4 is a mask such as a glass mask, a metal mask, and a stencil mask on which a predetermined pattern is formed, 11 is a half mirror, and 13 is a function for fixing the irradiated object 12 such as a vacuum chuck. It is a stage that is movable in the X, Y, Z axis directions and the θ direction and enables appropriate alignment of the laser light irradiation surface of the irradiated object 12.
[0026]
The laser light emitted from the laser oscillator 7 is reflected by the half mirror 11 through an optical system 9 (not shown) such as a beam expander or a homogenizer, a projection optical system 10 such as a mask 4 and a lens, and the transparent conductive material on the stage 13. The irradiated object 12 on which the film is formed is irradiated.
[0027]
The laser light to be irradiated is determined in consideration of various conditions such as the absorption edge wavelength of the transparent conductive film material to be a transparent electrode. In this example, an excimer laser (hereinafter simply referred to as a high output laser centered on the ultraviolet region). (Also referred to as laser light). Examples of the excimer laser medium include KrF (wavelength: 248 nm) and ArF (wavelength: 193 nm). Hereinafter, in this example, a KrF laser is used, and patterning is performed by irradiating a laser beam a predetermined number of times.
[0028]
Next, each of FIGS. 1A to 1E is a cross-sectional configuration diagram in each manufacturing process of a multilayer thin film for explaining the patterning method of the transparent conductive film of this example. For example, an acrylic resin, a polycarbonate resin, or the like is applied on a substrate 1 (FIG. 1A) such as glass, plastic, or silicon wafer, and post-baked to form a resin layer 2 (FIG. 1B). A transparent conductive film 3 made of, for example, an ITO (indium tin oxides) film or a ZnO film is vacuum-deposited on the resin layer 2 (FIG. 1C).
[0029]
When the transparent conductive film 3 thus formed is irradiated with, for example, KrF laser light from the laser oscillator 7 through the mask 4 (FIG. 1D), the transparent conductive film 3 irradiated with the laser light has a predetermined thickness of the mask 4. The laser beam 5 that passes through the pattern 4 a is absorbed, and the transmitted laser beam that has passed through the transparent conductive film 3 is absorbed by the resin layer 2. Then, in the transparent conductive film 3, ablation occurs due to the high energy of the laser beam 5 and thermal expansion occurs. Since the resin layer 2 also thermally expands, strain is generated at the interface between the transparent conductive film 3 and the resin layer 2, and a force that causes the transparent conductive film 3 to peel from the interface acts. Further, the vicinity of the surface of the resin layer 2 is also vaporized by ablation, and a force to lift the transparent conductive film 3 works. As a result, the transparent conductive film 3 explodes from the resin layer 2 (FIG. 1E).
[0030]
At this time, the irradiation energy density of the laser beam 5 applied to the transparent conductive film 3 is, for example, ± 0.05 J / cm with respect to an optimum value at which the transparent conductive film 3 can be removed from the resin layer 2.²If the thickness is within the range, the deformation of the pattern due to the thermal influence and the damage of the resin layer 2 can be minimized, and a good pattern shape can be obtained. The damage of the resin layer 2 at this time is suppressed to 5% or less in terms of the film thickness ratio (in the experiment, a result of 2% or less in the film thickness ratio was obtained). Of course, these numerical values vary depending on various conditions such as material and film thickness.
[0031]
Hereinafter, for example, the linear expansion coefficient of the material constituting the transparent conductive film 3 and the resin layer 2 is shown as follows:
ITO: 4-5 × 10^-6/ K,
Acrylic resin, polycarbonate resin: 6 × 10^-Five/ K
It is.
[0032]
As described above, by patterning the transparent conductive film 3 on the resin layer 2 by laser light irradiation, high-quality patterning is facilitated with a reduced process. Further, the conventional photolithography process is not required, and the manufacturing cost can be reduced due to the reduction of the work constant and the accompanying footprint.
[0033]
Next, another example of the embodiment of the patterning method for the transparent conductive film of the present invention will be described. 2A to F show cross-sectional configuration diagrams in the respective manufacturing steps of the multilayer thin film. In FIG. 2, parts corresponding to those in FIG. The laser patterning apparatus used for patterning the transparent conductive film 3 of this example has the same configuration as that shown in FIG.
[0034]
FIG. 2 is similar to the multilayer thin film described in FIGS. 1A to 1C. For example, an acrylic resin, a polycarbonate resin, or the like is applied and post-baked on a substrate 1 (FIG. 2A) such as glass, plastic, or silicon wafer. A resin layer 2 is formed (FIG. 2B). A transparent conductive film 3 such as an ITO film or a ZnO film is vacuum-deposited on the resin layer 2 (FIG. 2C). In this example, the metal film 6 is further vacuum-deposited on the transparent conductive film 3 to obtain a multilayer thin film (FIG. 2D), and the transparent conductive film 3 is patterned.
[0035]
The laser beam irradiation method is the same as that in FIG. 1, but the laser beam irradiation energy density needs to be varied depending on the optical characteristics, film thickness, and the like of the metal film 6. When the metal film 6 is irradiated with laser light through the mask 4 (FIG. 2E), melting and separation occur, but at the same time, the lower transparent conductive film 3 is thermally affected. And the transparent conductive film 3 peels from the interface of the resin layer 2 on the same principle as the example of FIG. 1, and the surface of the resin layer 2 is vaporized because the thermal effect is dominant. Further, the lifted transparent conductive film 3 explosively separates from the interface of the resin layer 2 and simultaneously disengages the upper metal film 6 (FIG. 2F). If the transparent conductive film 3 is not provided, an extra laser beam irradiation energy is required for removing the metal film 6, resulting in the etching of the resin layer 2, and the melt of the metal film 6. Tends to remain on the resin layer 2.
[0036]
Thus, by patterning the metal film 6 simultaneously with the transparent conductive film 3 by laser light irradiation, the peeling of the transparent conductive film 3 helps and the patterning of the metal film 6 becomes easy.
[0037]
Next, another example of the embodiment of the patterning method for the transparent conductive film of the present invention will be described. FIG. 4 shows an example of a laser patterning device having a local exhaust function. In FIG. 4, parts corresponding to those in FIG. In FIG. 4, a local exhaust means is provided between the laser beam paths of the half mirror 11 and the stage 13 of FIG. 3, and other basic configurations such as a laser oscillator and an optical system are the same as those of the laser patterning apparatus shown in FIG.
[0038]
As shown in FIG. 4, on the laser beam path 8 immediately before the laser beam is irradiated onto the irradiation object 12 on the stage 13, for example, the KrF laser is made of quartz, and the ArF laser is made of calcium fluoride. A substantially cylindrical decompression chamber 15 made of aluminum, stainless steel, or the like, provided with an upper transmission window 14 and a lower transmission window 16 through which an excimer laser passes, is provided, and the decompression chamber bottom 18 of the decompression chamber 15 has a local exhaust function.
[0039]
FIG. 5 shows a bottom view of the decompression chamber of FIG. A lower transmission window 16 that transmits laser light is provided at the center of the decompression chamber bottom 18, and several exhaust holes 19 are formed on a concentric circumference around the outer periphery of the decompression chamber bottom 18. A vacuum is drawn by the pump 17 (in this example, a maximum of 10^-2The atmosphere around the surface of the irradiated object 12 is exhausted through the exhaust hole 19.
[0040]
The distance between the lower transmission window 16 of the vacuum chamber bottom 18 and the irradiation surface of the irradiation object 12 is kept at 100 μm or less, and the conductance when exhausting through the exhaust hole 19 is thereby reduced. The degree of vacuum in the space between the bottom 18 and the irradiation object 12 is less than 1 atmosphere. The transparent conductive film 3 irradiated and removed under this reduced pressure has a higher sublimation pressure when leaving the interface with the resin layer 2 than when irradiated with the laser light at 1 atm. Irradiation energy density can be reduced. Further, the removed transparent conductive film 3 passes through the exhaust hole 19 and is taken into the decompression chamber 15. Thereby, the reattachment of the splash of the transparent conductive film 3 to the surface of the irradiated object 12 and the adhesion to the lower transmission window 16 can be prevented, and the surface of the irradiated object 12 and the lower transmission window 16 can be hardly contaminated.
[0041]
In this way, the laser light irradiation surface is made into a reduced pressure atmosphere with a simple configuration provided with a local exhaust function, and by irradiating the laser light in this reduced pressure atmosphere, the processing energy is reduced and the laser light irradiation is performed without impairing the productivity. The re-adhesion of the splash of the transparent conductive film 3 separated from the resin layer 2 and the adhesion of the splash to the lower transmission window 16 can be prevented.
[0042]
Next, another example of the embodiment of the patterning method for the transparent conductive film of the present invention will be described. FIG. 6 shows an example of a laser patterning apparatus having a local exhaust function and a gas introduction function. In FIG. 6, parts corresponding to those in FIGS. 3 and 4 are denoted by the same reference numerals. In FIG. 6, the local exhaust means of FIG. 4 is further provided with a gas introduction means, and other basic configurations such as a laser oscillator and an optical system are the same as those of the laser patterning apparatus shown in FIGS.
[0043]
As shown in FIG. 6, the upper transmission window 14 and the lower transmission window 16 through which the laser light is transmitted are provided on the laser optical path 8 immediately before the laser beam is irradiated onto the irradiation object 12 on the stage 13 as in FIG. A cylindrical decompression chamber 15 is provided, and the decompression chamber bottom 28 of the decompression chamber 15 is provided with a gas introduction function in addition to the local exhaust function.
[0044]
FIG. 7 shows a bottom view of the decompression chamber of FIG. A lower transmission window 16 that transmits laser light is provided at the center of the decompression chamber bottom portion 28, and an exhaust hole 19 is formed on a concentric circumference around the outer peripheral portion. The exhaust hole 17 is provided by an external roughing pump 17. The atmosphere is suctioned through 19. Further, several gas introduction holes 21 are formed on the concentric circumference between the lower transmission window 16 and the exhaust hole 19 as described above. In the case of a pulse laser such as the excimer laser of this example when an active gas is introduced into the laser beam irradiation surface of the object to be irradiated 12, the active gas is not irradiated during a predetermined number of times of laser beam irradiation until the patterning of the transparent conductive film 3 is completed. The active gas is introduced. Similarly, in the case of a continuous wave laser, the inert gas is introduced until the patterning is completed.
[0045]
The introduction of the inert gas is performed immediately before laser beam irradiation, that is, patterning, and the irradiation surface of the irradiation object 12 before introduction is reduced to 1 atm or less by atmospheric suction through the exhaust hole 19 as described in the example of FIGS. It has an atmosphere. Therefore, when an inert gas is introduced, a flow of the inert gas due to the generated pressure difference is generated, and the gas is sucked into the exhaust hole 19 along the surface of the irradiated object 12, and the laser beam irradiation surface on the inner peripheral side In addition, once the gas is accumulated, the accumulated gas is exhausted through the exhaust hole 19. In this example, a laser beam is irradiated at the moment when the inert gas accumulates on the laser beam irradiation surface, and the removed transparent conductive film 3 is efficiently taken into the decompression chamber 15 by the above-described gas flow and viscous flow. .
[0046]
As described above, by using the laser patterning apparatus having the local exhaust function and the gas introduction function, the splash of the transparent conductive film 3 separated from the resin layer 2 can be efficiently removed by the viscous flow of the inert gas. Can do.
[0047]
Next, another example of the embodiment of the patterning method for the transparent conductive film of the present invention will be described. FIG. 8 shows a cross-sectional configuration diagram of a multilayer thin film for explanation of this example. In FIG. 8, parts corresponding to those in FIG. In FIG. 8, the first resin layer 22 and the second resin layer 23 are formed on the substrate 1, and the transparent conductive film 3 is further formed on the second resin layer. Here, it is assumed that the first resin layer 22 is made of a material that absorbs laser light in the ultraviolet region than the second resin layer 23.
[0048]
Then, the multilayer thin film is irradiated with laser light using a laser patterning apparatus as shown in FIG. 3, and the ablation of the transparent conductive film 3, the transparent conductive film 3 and the second resin layer 23, as in the example of FIG. Since the transparent conductive film 3 can be removed with low irradiation energy using the distortion of the interface due to the difference in the linear expansion coefficient, damage to the first resin layer 22 due to the transmitted laser light can be suppressed.
[0049]
Next, another example of the embodiment of the patterning method for the transparent conductive film of the present invention will be described. FIG. 9 shows a cross-sectional configuration diagram of a multilayer thin film for explanation of this example. In FIG. 9, parts corresponding to those in FIG. In the figure, a first resin layer 22 formed in a partial region on the substrate 1 is, for example, an acrylic photosensitive resin containing a black pigment, and is processed into a predetermined pattern. The second resin layer 23 formed on the substrate 1 so as to cover the first resin layer 22 is, for example, a transparent acrylic photosensitive resin containing no pigment. A transparent conductive film 3 is formed on the uppermost layer on the second resin layer 23. Here, a region on the substrate 1 where the first resin layer 22 is not present is A, and a region where the first resin layer 23 is present is B. In this configuration, the absorption rate of the laser beam in the ultraviolet region is higher in the region B than in the divided region A including the first resin layer 22.
[0050]
10A and 10B show an example of a mask used for laser patterning of the multilayer thin film as shown in FIG. 10A is a top view of the mask (here, the quartz 25 is shown through), and FIG. 10B is a cross-sectional view taken along the line BB of FIG. 10A.
[0051]
As shown in FIG. 10B, the mask is configured by forming a laser light shielding layer 24 having a predetermined pattern on a transparent substrate such as quartz 25. For the laser light shielding layer 24, for example, a chromium (Cr) film or the like is used. The pattern 24A on the right side of FIGS. 10A and 10B is used for patterning the region A of the multilayer thin film in FIG.
[0052]
The pattern opening of the mask has a lower laser beam transmittance in the region B than in the region A. The transmittance is adjusted in advance according to the optical characteristics of the irradiated object 12 in the laser beam shielding layer 24. The film thickness is varied according to the pattern shape. For example, when the chromium film has a film thickness of 85 nm, the transmittance of the laser beam in the ultraviolet region is approximately 0%, but when the film thickness is 50 nm, the transmittance is approximately 30%. Thus, the energy irradiated to the irradiation surface can be varied by adjusting the film thickness of the pattern opening of the mask in advance.
[0053]
The mask shown in FIG. 10 is used for the mask 4 of the laser patterning apparatus shown in FIG. 3, for example, so that an attenuator is provided on the laser light path when patterning the transparent conductive film 3 and the irradiation energy of the laser light is conventionally provided. The output energy of the laser oscillator 7 can be kept constant. In addition, multilayer thin films having different absorption rates of laser light can be simultaneously patterned by one laser light irradiation.
[0054]
8, 9, and 10, in addition to the laser patterning device shown in FIG. 3, a laser patterning device having a local exhaust function as shown in FIG. 4 is used to irradiate laser light under reduced pressure. Further, it is possible to reduce the processing energy to be irradiated and to prevent re-adhesion of the splash of the transparent conductive film 3 separated from the resin layer by the laser beam irradiation.
[0055]
Similarly, in FIG. 8, FIG. 9 and FIG. 10, the splash of the transparent conductive film 3 separated from the resin layer by using a laser patterning device having a local exhaust function and a gas introduction function as shown in FIG. Can be efficiently removed by a viscous flow of inert gas.
[0056]
Next, another example of the embodiment of the patterning method for the transparent conductive film of the present invention will be described. In general, an ITO film is used as the transparent conductive film 3 constituting each of the multilayer thin films in FIGS. 1, 2, 8, and 9, and hydrogen bromide (HBr), hydrogen iodide (HI), etc. that react with ITO are used. A dry etching method using a reactive gas in an RIE (reactive ion etching) process is widely known. In this example, the present invention is applied to this RIE process, gas is dissociated using a high energy excimer laser or the like, and indium oxide (In) generated from the ITO film irradiated with laser light₂O_Three) To increase the ablation effect.
[0057]
For example, after introducing hydrogen bromide by the gas inlet means 20 in a reduced pressure atmosphere where the irradiation surface of the irradiation object 12 is 1 atm or less using the laser patterning apparatus of FIG. 6 having a local exhaust function and a gas introduction function. When irradiated with laser light, it reacts with indium oxide on the ITO film to produce indium bromide (In₂Br_Three) And when hydrogen iodide is used, indium iodide (InI_Three) To promote separation from the resin layer.
[0058]
This facilitates removal of the ITO film due to a synergistic effect with ablation. Then, the generated indium bromide or indium iodide and the splash of the ITO film separated from the resin layer are taken into the decompression chamber 15 through the discharge hole 19 by the viscous flow, and are efficiently removed from the irradiation surface.
[0059]
It should be noted that the present invention is not limited to the above-described embodiments, and various other configurations can be taken without departing from the gist of the present invention.
[0060]
【The invention's effect】
  According to the present invention, the resin layer formed on the transparent resin layerThanLinear expansion coefficientIs smallmaterialConsist ofFor transparent conductive film,Patterned through the maskOf a given energy densitySince the laser beam was irradiated, ablation of this transparent conductive film,Thermally expandedThe transparent conductive film is formed by utilizing the distortion of the interface due to the difference in the linear expansion coefficient between the transparent conductive film and the resin layer and the vaporization by the ablation of the resin layer surface.It is formed even after laser light irradiationResin layerUpThe transparent conductive film can be selectively patterned by explosive separation from the surface, making high-quality patterning easy with a reduced process and eliminating the need for a conventional photolithography process. There is a benefit that productivity can be improved and manufacturing costs can be reduced due to the reduction and the accompanying footprint reduction.
[0061]
  In the present invention, when the transparent conductive film on the resin layer and the metal film formed thereon are irradiated with a laser beam patterned through a mask, the metal film is melted and A transparent conductive film that uses the strain at the interface due to the difference in linear expansion coefficient between the transparent conductive film and the resin layer and the vaporization due to the thermal effect on the surface of the resin layer. TheIt is formed even after laser light irradiationResin layerUpSince it can be explosively detached from the metal layer and removed together with the upper metal film, peeling of the transparent conductive film is helpful and there is an advantage that the metal film can be easily patterned.
[0062]
Further, in the present invention, the surface where the exhaust holes of the local exhaust means are opened is placed in close proximity to the transparent conductive film formed on the resin layer or further to the metal film formed thereon. When the atmosphere in the vicinity of the laser light irradiation surface of this transparent conductive film or metal film is exhausted from this exhaust hole and this laser light is irradiated in a reduced pressure atmosphere, the laser light irradiation surface is configured with a simple configuration. By irradiating with laser light in this reduced-pressure atmosphere, the irradiation energy required for patterning can be reduced without impairing productivity, and splashes of the transparent conductive film detached from the resin layer are removed through the exhaust holes. Therefore, there is an advantage that the redeposition and contamination of the splash can be prevented and the quality of the multilayer thin film is improved.
[0063]
Further, in the present invention, an exhaust hole for performing local exhaust and one surface of the local exhaust / gas introduction means having a gas introduction hole for introducing gas on the inner peripheral side of the exhaust hole are formed on the resin layer. Is placed in close proximity to the transparent conductive film or the metal film formed thereon, and the atmosphere in the vicinity of the laser light irradiation surface of the transparent conductive film or metal film is exhausted from the exhaust hole to form a reduced-pressure atmosphere. Further, when an inert gas is introduced from the gas introduction hole to the laser light irradiation surface of the transparent conductive film immediately before the laser light irradiation and the laser light is irradiated, the laser on the inner peripheral side of the exhaust hole is used. As the inert gas accumulates on the light irradiation surface, the laser beam is irradiated, and the splashes separated from the resin layer and removed can be efficiently removed through the exhaust holes by the viscous flow of the inert gas. Spray re-adhesion and contamination There is a benefit to improve the quality of the multi-layer thin film can be stopped.
[0064]
Further, in the present invention, an exhaust hole for performing local exhaust and one surface of the local exhaust / gas introduction means having a gas introduction hole for introducing gas on the inner peripheral side of the exhaust hole are formed on the resin layer. Is placed in close proximity to the transparent conductive film or the metal film formed thereon, and the atmosphere in the vicinity of the laser light irradiation surface of the transparent conductive film or metal film is exhausted from the exhaust hole to form a reduced-pressure atmosphere. Further, when a reactive gas with the transparent conductive film is introduced from the gas introduction hole to the laser light irradiation surface of the transparent conductive film immediately before the laser light irradiation, and the laser light is irradiated, The synergistic effect of chemical reaction and ablation between the irradiated transparent conductive film and reactive gas facilitates removal and removal of the transparent conductive film from the resin layer, and the resulting transparent conductive film and reactivity. Compounds with gases and Since the droplets of the transparent conductive film emerged can be efficiently removed from the exhaust hole by viscous flow, there is a benefit to improve the quality of the multilayer thin film can be prevented from re-adhesion or contamination of splash.
[0065]
  Further, according to the present invention, the second resin layer formed on the first resin layer containing the pigment on the multilayer thin film substrate and the transparent second resin layer thereon.ThanLinear expansion coefficientIs smallTo transparent conductive film made of material,Of a given energy densitySince the laser light was irradiated and the laser light irradiated portion of the transparent conductive film was peeled off from the second resin layer and patterned, ablation of the transparent conductive film,Thermally expandedUsing the distortion of the interface due to the difference in linear expansion coefficient between the transparent conductive film and the second resin layer and the vaporization due to the ablation of the second resin layer surface,Transparent conductive filmIt is formed even after laser light irradiationSecond resin layerUpFromExplosivelyRemove and removeShiThe irradiation energy of the laser beam can be reduced, and the transparent conductive film can be patterned without damaging the first resin layer, so that there is an advantage that the quality of the multilayer thin film is improved.
[0066]
  Further, according to the present invention, the multilayer thin film is formed in a partial region on the substrate.Contains pigmentA second resin layer formed on this substrate including the first resin layer and a film formed thereonIt is made of a material having a linear expansion coefficient different from that of the second resin layer.The transparent conductive film is irradiated with the laser light through a mask whose transmittance varies stepwise by changing the film thickness, and the region where the first resin layer is formed by this mask and other regions. Since the irradiation energy density to the transparent conductive film is varied and patterned, the transparent conductive film on the plurality of resin layers having different laser light absorption rates can be irradiated differently while keeping the output energy of the laser light stable. Since patterning can be performed simultaneously with laser light having an energy density, there is an advantage that the quality and productivity of the multilayer thin film are improved.
[Brief description of the drawings]
FIGS. 1A to 1E are cross-sectional configuration diagrams in respective manufacturing steps of a multilayer thin film for explaining an example of an embodiment of a patterning method for a transparent conductive film of the present invention.
FIGS. 2A to 2F are cross-sectional configuration diagrams in respective manufacturing steps of a multilayer thin film for explaining another example of the embodiment of the patterning method of the transparent conductive film of the present invention.
FIG. 3 is a block diagram showing an example of a laser beam patterning device used in the patterning method for a transparent conductive film of the present invention.
FIG. 4 is a configuration diagram showing an example of a laser beam patterning device used in the method for patterning a transparent conductive film of the present invention.
5 is a bottom view of the decompression chamber of FIG. 4. FIG.
FIG. 6 is a schematic configuration diagram showing an example of a laser beam patterning device used in the patterning method for a transparent conductive film of the present invention.
7 is a bottom view of the decompression chamber of FIG. 6. FIG.
FIG. 8 is a cross-sectional configuration diagram of a multilayer thin film for explaining another example of the embodiment of the patterning method of the transparent conductive film of the present invention.
FIG. 9 is a cross-sectional configuration diagram of a multilayer thin film for explaining another example of the embodiment of the patterning method of the transparent conductive film of the present invention.
FIG. 10 shows an example of a mask used in the method for patterning a transparent conductive film of the present invention, in which A is a top view and B is a cross-sectional view along line BB of A. FIG.
FIGS. 11A to 11E are cross-sectional configuration diagrams in each manufacturing process for explaining a photolithography process. FIGS.
[Explanation of symbols]
1 ... substrate, 2 ... resin layer, 3 ... transparent conductive film, 4 ... mask, 5 ... laser light, 6 ... metal film, 7 ... ..Laser oscillator, 8... Laser beam path, 12... Irradiated object, 14... Upper transmission window, 15. ... Roughing pump, 18 ... Vacuum chamber bottom, 19 ... Exhaust hole, 20 ... Gas introduction means, 21 ... Gas introduction hole, 22 ... First Resin layer, 23 ... second resin layer, 24 ... laser light blocking layer, 24A, 24B ... pattern, 25 ... quartz

Claims (5)

A transparent resin layer is formed on the substrate,
Linear expansion coefficient than the transparent resin layer is a transparent conductive film made of little material on the transparent resin layer,
Irradiating the transparent conductive film surface with laser light having a predetermined energy density that is patterned through a mask by a projection optical system,
In the step of patterning by detaching and removing the laser light irradiated portion of the transparent conductive film from the transparent resin layer formed after the laser light irradiation ,
Distortion that occurs at the interface between the transparent conductive film and the transparent resin layer that is thermally expanded due to the energy of the laser light being absorbed by the transparent conductive film and the transparent resin layer by irradiation with the laser beam having the predetermined energy density. The method of manufacturing a display device having a transparent conductive film in which the transparent conductive film that has been ablated is peeled off and the transparent conductive film is released by vaporization that occurs on the surface of the transparent resin layer . In the manufacturing method of the display apparatus which has a transparent conductive film of Claim 1 ,
The said transparent resin layer is an acrylic resin The manufacturing method of the display apparatus which has a transparent conductive film. Forming a first resin layer made of a resin containing a pigment on a substrate;
Forming a second resin layer made of a transparent resin on the first resin layer;
A transparent conductive film made of a material having a smaller linear expansion coefficient than the second resin layer is formed on the second resin layer,
Irradiating the transparent conductive film surface with laser light having a predetermined energy density that is patterned through a mask by a projection optical system,
The second resin layer is interposed between the first resin layer and the transparent conductive film, which has a higher laser light absorption rate than the second resin layer, and is formed even after the laser light irradiation. In the step of patterning by detaching and removing the laser light irradiated portion of the transparent conductive film from the second resin layer ,
By the irradiation of the laser beam having the predetermined energy density, the energy of the laser beam is absorbed by the transparent conductive film and the second resin layer, and the thermally expanded interface between the transparent conductive film and the second resin layer. A method of manufacturing a display device having a transparent conductive film in which the transparent conductive film that has been ablated is peeled off due to strain generated in the substrate, and the transparent conductive film is released by vaporization that occurs on the surface of the second resin layer . In the manufacturing method of the display apparatus which has a transparent conductive film of Claim 3 ,
Forming a first resin layer on a part of the area on the substrate,
Forming a second resin layer on the substrate including the first resin layer,
The transparent conductive film formed on the second resin layer is irradiated with the laser light through the mask whose transmittance varies stepwise by changing the film thickness,
A method of manufacturing a display device having a transparent conductive film, wherein the irradiation energy density to the transparent conductive film is varied and patterned in a region where the first resin layer is formed by the mask and another region. In the manufacturing method of the display apparatus which has a transparent conductive film of Claim 4 ,
The said 1st and 2nd resin layer is an acrylic resin The manufacturing method of the display apparatus which has a transparent conductive film.

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