JP2000328229A - Vacuum deposition device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vacuum deposition device capable of easily removing an organic film or an organometallic film deposited on a masking plate. SOLUTION: In a vacuum deposition device having an evaporation source, capable of vaporizing an organic material or an organometallic material from the evaporation source and using a masking plate in order to deposit an organic film or an organometallic film on only specified part of a base plate, a means, which is able to remove the organic film or the organometallic film deposited on the masking plate by vacuum deposition in the presence of plasma, is provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum evaporation apparatus, and more particularly to a film formation apparatus using a masking plate such as an organic electroluminescent display which requires a masking film formation.

[0002]

2. Description of the Related Art In recent years, organic electroluminescent elements (hereinafter referred to as organic EL elements) which are self-luminous devices.
Has been researched and developed for use in small displays and the like. However, in order to open that market, it is necessary to break through the walls of liquid crystal panels, and it is difficult to open that market unless the advantage of reducing power consumption is secured. Attention has been focused on panels for automobiles. Organic EL is self-luminous, has high visibility in bright and dark places, and solves the problem of power consumption because it is mounted on a car.

[0003] Generally, a deposited film of an organic EL element is formed on a substrate by a vacuum evaporation method or a sputtering method. In particular, in the manufacture of a display, patterning is performed by a film forming technique using a masking plate having an opening. Is required.

However, if an organic film accumulates on the masking plate during repeated film formation, the masking opening may be clogged, or a pattern shift may occur due to the effect of the deposited film, resulting in a defective element. Becomes In order to prevent this, generally, the vacuum chamber is opened to the atmosphere, the masking plate is taken out, and the organic film is removed or replaced with a new masking plate. As a method of removing the organic film, a general method of regenerating a masking plate is to take out the film into the atmosphere and dissolve the organic film with an organic solvent, or to scrape the organic film by a method such as blasting.

A method of removing a deposited film in a vacuum in a conventional vacuum processing apparatus is disclosed in, for example, Japanese Patent Application Laid-Open No. Hei 8-31958.
As disclosed in Japanese Unexamined Patent Publication No. 6-106, a method of etching a film (residual product) by flowing an etching gas to generate plasma. This method generally uses a plasma CV having an electrode for plasma generation in a vacuum chamber.
It is used for film removal of D equipment and etching equipment, and removal of by-products. However, it is not used in a sputtering apparatus or a vapor deposition apparatus using an evaporation source crucible having a film forming material in a vacuum chamber. This is because the target material bonded to the cathode and the material in the crucible are etched by the radical of the reaction gas.

[0006]

However, a conventional apparatus for removing an organic film on a masking plate by once opening a vacuum chamber to the atmosphere or an apparatus for removing a film by flowing a reaction gas in a vacuum to generate plasma. Had the following problems.

[0007] 1. Generally, it is known that an organic material has a hygroscopic property, and the life of an organic EL element or the like is significantly reduced unless degassing or dehydration of the material is sufficiently performed.
Once the vacuum chamber is opened to the atmosphere, it takes time to return to a film-forming state (a state in which the water in the vacuum chamber and the organic material has been removed), and the production efficiency decreases. 2. When the masking plate is replaced, it is necessary to perform the positioning of the masking plate each time. In this operation, it is necessary to perform positioning with an accuracy of several tens of microns to several microns, and it is necessary to attach a position adjusting mechanism. 3. When a gas containing oxygen or the like is introduced into the processing chamber, plasma is generated by a parallel plate electrode for generating plasma in the processing chamber, and the organic film is removed. The surface of the inner wall exposed to the plasma is cleaned, but the masking plate is 2 mm thick and the groove width is 1 mm.
It was difficult to remove the organic film deposited on the side wall of the groove in units of / 10 mm or on the edge of the groove of the masking plate on the side in contact with the substrate. As a result, even if the built-in components other than the masking plate are cleaned by the plasma, the defective portion of the organic EL element does not decrease because the cleaning of the groove side wall portion of the masking plate that is most desired to be cleaned is incomplete. 4. If an attempt is made to remove the organic film by plasma, even the organic material in the crucible is etched by radicals of the reaction gas.

SUMMARY OF THE INVENTION The present invention has been made to solve such disadvantages of the prior art. An organic material or an organic metal material is evaporated only from a specific portion on a substrate by evaporating an organic material or an organic metal material from an evaporation source. An object of the present invention is to provide a vacuum evaporation apparatus using a masking plate for depositing an organic film or an organic metal film deposited on the masking plate, which can be easily removed without breaking vacuum. Is what you do.

[0009]

That is, the present invention comprises an evaporation source, an organic material or an organic metal material is evaporated from the evaporation source, and an organic film or an organic metal film is deposited only on a specific portion on the substrate. A vacuum evaporation apparatus using a masking plate, comprising: means for removing an organic film or an organic metal film deposited on the masking plate by vacuum evaporation in the presence of plasma.

The means (reproducing means or cleaning means for the masking plate) introduces a gas containing oxygen, supplies power for generating plasma to the masking plate, and generates plasma only in the vicinity of the masking plate to generate plasma. It is preferable to include means for removing the organic film or the organic metal film deposited on the substrate.

The regenerating means or the cleaning means introduces an oxygen-containing gas, provides an electrode for generating plasma in addition to the masking plate, applies a bias to the masking plate, and applies plasma only to the periphery of the masking plate. It is preferable to include a means for removing the organic film or the organic metal film generated and deposited on the masking plate.

It is preferable that the evaporation source has a shutter for preventing entry of oxygen radicals generated by plasma for removing the organic film or the organic metal film deposited on the masking plate. It is preferable that the organic material or the organic metal material is a material for an organic electroluminescent display.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION A vacuum deposition apparatus provided with a masking plate regeneration or cleaning mechanism according to the present invention includes an evaporation source, and evaporates an organic material or an organic metal material from the evaporation source to form an organic material only on a specific portion on a substrate. In a vacuum deposition apparatus using a masking plate for depositing a film or an organometallic film, the organic film or the organometallic film deposited on the masking plate by vacuum deposition generates plasma only in the in-plane peripheral region of the masking plate and generates a vacuum. It is characterized by comprising a regeneration (or cleaning) means for removing.

Specifically, the vacuum deposition apparatus of the present invention is provided with, for example, means for removing an organic film or an organic metal film deposited on an organic EL element, and has taken the following means to solve the above problems. There is a feature.

1. In a vacuum evaporation apparatus using a masking plate for depositing an organic film only on a specific portion on a substrate, provided with an evaporation source crucible, a plasma is generated only around the masking plate, and the organic film deposited on the masking plate or Only the organometallic film was removed in vacuum. In particular,
A shield plate and a shutter for sealing the plasma were arranged around the masking plate, and the plasma was sealed, and power for generating the plasma was supplied to the masking plate. The masking plate was connected so that a negative potential was applied. Since a negative potential is applied to the masking plate, the oxygen ions sneak into the groove of the masking plate, and the organic film or the organic metal film deposited up to the groove edge of the masking plate can be removed.

2. In a vacuum evaporation apparatus using a masking plate provided with an evaporation source crucible and depositing an organic film or an organometallic film only on a specific portion of a substrate, plasma is generated only around the masking plate and deposited on the masking plate. Only the organic film or the organic metal film thus removed was removed in vacuum. Specifically, a shield plate and a shutter for sealing the plasma were arranged around the masking plate, and the plasma was sealed, and power for generating the plasma was supplied to the deposition-preventing plate. Further, a negative bias potential was supplied to the masking plate. Since a negative potential was applied to the masking plate, oxygen ions spilled into the groove of the masking plate, and the organic film or the organic metal film deposited up to the groove edge of the masking plate could be removed.

3. In addition to the organic film or organic metal film removing means of the above 1 and 2, a shutter having a structure for preventing oxygen ions from entering the crucible was attached above the evaporation source crucible. This shutter eliminated the etching of the organic material or the organic metal material in the crucible.

The organic film or the organic metal film used in the present invention is, for example, an organic phosphoric acid compound, an organic phosphorous acid compound or a hypophosphorous acid compound.
No. 5, JP-A-11-16677 and the like, and examples thereof include compounds for forming a hole transfer layer for organic EL such as metal oxinoid compounds and tetraallyl diamine, and compounds for forming a hole injection layer such as metal phthalocyaninine compounds. Can be

The masking plate used in the present invention includes a stainless plate, a copper plate, an aluminum plate, a silver plate and the like, and has a thickness of 0.01 mm to 10 mm, preferably 0.1 mm to 1 mm.

[0020]

EXAMPLES The present invention will be specifically described below with reference to examples.

Embodiment 1 FIG. 1 is a schematic view showing an embodiment of the vacuum evaporation apparatus of the present invention. In FIG. 1, the masking plate 101 is fixed by a support member 106 which is an insulating material. The substrate 102 that has been subjected to the vacuum deposition processing is transported by the transport mechanism 112 through the substrate transport port 114, and is removed from the processing box that is the ground electrode 104 and also serves as a deposition prevention plate.

Substrate 1 treated by organic deposition source 105
After the removal of 02, the masking plate 101 connected to the power supply 107 is used as a cathode electrode, and the ground electrode 104, which also serves as a deposition-preventing plate, supplies oxygen from the gas inlet 111 to generate plasma. At that time, the deposition source 105
Therefore, the opening is closed by the shutter 113 because the plasma reaches the opening. It was confirmed that plasma was generated only in the discharge space 108 where the substrate 102 was present.

FIG. 2 shows a masking plate used in the first embodiment. The discharge conditions under which the organic film attached to the masking plate was removed are as follows.

Processing pressure 133 Pa Discharge power 13.56 MHz, 100 W Oxygen flow rate 50 sccm Processing time 10 min A test for removing and evaluating the organic film adhered to the masking plate was performed as follows.

After the pressure in the vacuum chamber is evacuated to 1 × 10 ⁻⁴ Pa or less, the crucible filled with the organic material evaporation source is heated to about 250 ° C.
To control. The deposition rate is confirmed to be stable (about 0.2 nm / s) by a quartz crystal film thickness monitor, and the shutter is opened to start film formation. After confirming that a film thickness of 0.3 μm has been formed on the quartz crystal film thickness monitor, close the shutter. Film formation with this film thickness was performed 10 times, and the formed pattern was measured.

The total film thickness deposited on the masking plate is about 3 μm.
m. FIG. 2 shows the masking plate pattern for the test. The holes are patterned so as to have a size of 50 μm square and the space between the holes is 30 μm.

In the first film formation, a masking plate of 50 μm
An organic material deposited layer could be formed within an error range of 49 μm square to 50 μm square corresponding to the square hole, but an error of 46 μm square to 49 μm square after 10 times of film formation. here,
After removing the organic film under the above discharge conditions, film formation was performed again. As a result of measuring the pattern, the area of the deposited layer is
It was within the error range of 49 μm square to 50 μm square.

From this result, it can be determined that the organic film attached to the masking plate has been removed by oxygen plasma.
In addition, since plasma power was directly applied to the masking plate, it was confirmed that plasma wraparound was good and that film removal at the edge of the groove of the masking plate was sufficiently performed.

Embodiment 2 FIG. 3 is a schematic view showing another embodiment of the vacuum evaporation apparatus of the present invention. The masking plate 301 is fixed by a support member 306 made of an insulating material. The processed substrate 302 is transported by the transport mechanism 312 from the substrate loading / unloading port 314, and is removed from the processing box which is the plasma electrode 304 and also serves as a deposition prevention plate. Plasma electrode 304 is surrounded by ground potential by shield box 315.

Substrate 3 treated by organic deposition source 305
After removing 02, the deposition plate 304 connected to the power supply 307 is used as a cathode electrode, and oxygen is supplied from the gas inlet 311 to generate plasma. At that time, since the plasma reaches the evaporation source 305, the shutter 31 is used.
Close the opening with 3. DC 200 is applied to the masking plate 301.
A bias potential of V was applied. It was confirmed that plasma was generated only in the discharge space 308 where the substrate 302 was present.

FIG. 2 shows a masking plate used in the second embodiment. The discharge conditions under which the organic film attached to the masking plate was removed are as follows.

Processing pressure 133 Pa Discharge power 13.56 MHz, 100 W Oxygen flow rate 50 sccm Processing time 10 min A test for removing and evaluating the organic film adhered to the masking plate was performed as follows.

After the pressure in the vacuum chamber was evacuated to 1 × 10 ⁻⁴ Pa or less, the crucible filled with the organic metal material evaporation source was discharged for about 25 minutes.
Control at 0 ° C. The deposition rate was confirmed to be stable (approximately 0.2 nm / s) by a quartz crystal film thickness monitor.
Open the shutter and start film formation. After confirming that a film thickness of 0.3 μm has been formed on the quartz crystal film thickness monitor, close the shutter. Film formation with this film thickness was performed 10 times, and the formed pattern was measured.

The total film thickness deposited on the masking plate is about 3 μm.
m. FIG. 2 shows the masking plate pattern for the test. The holes are patterned so as to have a size of 50 μm square and the space between the holes is 30 μm.

In the first film formation, the masking plate 50 μm
While the deposited layer of the organometallic material could be formed in an error range of 49 μm square to 50 μm square corresponding to the hole of m square,
After the first film formation, an error of 46 μm square to 49 μm square was obtained.
Here, the organic metal film was removed under the above discharge conditions, and then the film was formed again. As a result of measuring the pattern, the area of the deposited layer was within the error range of 49 μm square to 50 μm square.

From this result, it can be determined that the organometallic film attached to the masking plate has been removed by the oxygen plasma. In addition, since the bias potential was applied to the masking plate, it was confirmed that the wraparound of the plasma was good and that the film removal at the edge of the groove of the masking plate was sufficiently performed.

Embodiment 3 FIG. 4 is a schematic view showing a structure of a shutter for preventing radicals of an etching gas from entering an evaporation source. 401
, An evaporation source, 402, a shutter plate for preventing radicals of the etching gas from entering, 403, an arm for supporting the shutter, 404, a rotating shaft for rotating the shutter,
405 is a seal member for vacuum-sealing the rotating shaft, 406 is a bellows for sealing the rotating shaft that moves up and down, 407 is a coupling for connecting the rotating shaft to a motor which is a power source of rotation, and 408 is for rotating the shutter. And 409, an air cylinder for moving the shutter up and down.

When etching the organic film adhered to the masking plate with oxygen plasma, the shutter 402 is closed, the air cylinder 409 is lowered, and the shutter 402 is brought into close contact with the evaporation source to prevent oxygen radicals from entering. The organic material in the evaporation source crucible was not etched by the shutter 402 during the film removal by the oxygen plasma.

[0039]

As described above, according to the present invention, the following effects can be obtained. 1) After film formation, the organic film or the organic metal film can be easily removed,
Since cleaning becomes possible every time, patterning accuracy with good reproducibility can be obtained as shown in the embodiment. 2) The cycle of opening the vacuum chamber to the atmosphere is extended. The vacuum chamber may be opened to the atmosphere during the material charging cycle, and at least two to three times as long as there is no cleaning mechanism (depending on the material charging amount and film thickness). Vacuum chamber,
Once released to the atmosphere, the film can be formed (vacuum pressure,
It takes 9 hours for evacuation, 3 hours for baking, and 5 hours for evacuation after baking before returning to the state of moisture and the like). Since the number of times that this time is required is reduced, the production efficiency is improved.

3) Since the mask is not removed at the time of maintenance, the position adjustment of the mask is performed only when the mask is first set, and the mechanism for adjusting the position of the mask is not required. The price of the mask position adjusting mechanism differs depending on the method and shape, but the cost is greatly reduced. 4) The time required for mask position adjustment when changing the mask is as follows:
Approximately four hours are required each time, but this time is unnecessary. 5) Since the shutter for preventing radicals of the etching gas from entering the evaporation source crucible is provided, the material in the crucible is not removed.

[Brief description of the drawings]

FIG. 1 is a schematic view showing one embodiment of a vacuum evaporation apparatus of the present invention.

FIG. 2 is an explanatory view showing a masking plate used in an example.

FIG. 3 is a schematic view showing another embodiment of the vacuum evaporation apparatus of the present invention.

FIG. 4 is a schematic view showing a structure of a shutter for preventing radicals of an etching gas from entering an evaporation source.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 101 Masking plate 102 Substrate 103 Vacuum processing chamber 104 Ground electrode 105 Organic vapor deposition source 106 Masking support member 107 Power supply 108 Discharge space 109 Exhaust port a 110 Exhaust port blll Gas inlet 112 Substrate transfer mechanism 113 Shutter 114 Substrate carry-in / out 201 Opening edge Section 202 Substrate contact surface 301 Masking plate 302 Substrate 303 Vacuum processing chamber 304 Plasma electrode (proof plate) 305 Organic vapor deposition source 306 Masking support member 307 Power supply 308 Discharge space 309 Exhaust port a 310 Exhaust port b 311 Gas inlet 312 Substrate transport Mechanism 313 Shutter 314 Substrate loading / unloading port 315 Earth shield box 401 Evaporation source 402 Shutter 403 Arm 404 Rotating shaft 405 Seal member 406 Vacuum bellows 407 Coupling 408 rotation for the motor 409 air cylinder

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Kazunori Ueno 3-30-2 Shimomaruko, Ota-ku, Tokyo F-term in Canon Inc. (reference) 4K029 BA62 CA01 DA09 DA12 HA03 4K057 DA01 DB17 DD01 DE20 DM40 5G435 AA17 BB05 EE33 KK05 KK10

Claims (5)

[Claims] 1. A vacuum vapor deposition apparatus comprising a vaporization source, a masking plate for evaporating an organic material or an organic metal material from the evaporation source, and depositing an organic film or an organic metal film only on a specific portion on a substrate, A vacuum deposition apparatus comprising: means for removing an organic film or an organic metal film deposited on a masking plate by vacuum deposition in the presence of plasma. 2. The means for introducing a gas containing oxygen,
2. The vacuum vapor deposition apparatus according to claim 1, further comprising means for supplying power for generating plasma to the masking plate to generate plasma only in the vicinity of the masking plate to remove an organic film or an organic metal film deposited on the masking plate. 3. The means for introducing a gas containing oxygen,
An electrode for generating plasma other than the masking plate is provided, and a bias is applied to the masking plate to generate plasma only in the vicinity of the masking plate to remove an organic film or an organic metal film deposited on the masking plate. The vacuum evaporation apparatus according to claim 1. 4. The apparatus according to claim 1, wherein the evaporation source has a shutter for preventing entry of oxygen radicals generated by plasma for removing an organic film or an organic metal film deposited on the masking plate. 5. The vacuum deposition apparatus according to item 1. 5. The vacuum evaporation apparatus according to claim 1, wherein the organic material or the organic metal material is a material for an organic electroluminescence display.