JP3441002B2 - Sputtering equipment - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sputtering apparatus for depositing a film on a substrate by sputtering a plurality of targets while moving the substrate, and in particular, it monitors the temperature of the substrate on which the film is formed at all times. The present invention relates to a sputtering apparatus having a controlled substrate heating movement mechanism.

[0002]

2. Description of the Related Art In recent years, many high-performance devices have been developed along with the progress of thin film manufacturing technology. A sputtering method is a typical method for forming the thin film. When the sputtering method is classified from the viewpoint of the number of target targets used, a single target sputtering method (hereinafter referred to as a single sputtering method) and a multi-source target sputtering method (hereinafter referred to as a multi-source sputtering method). .) Can be divided into. The former is a method of forming a film with one target, and usually a target having the same composition as the film to be formed is used. In this case, it is necessary to optimize the film formation conditions (substrate temperature, sputtering pressure, gas type, etc.) in order to obtain the target film. If the desired film cannot be obtained even if the film forming conditions are optimized, it is necessary to change the composition of the target. The latter is a method of forming a film using a plurality of targets, and when the target film is composed of a plurality of elements, a plurality of targets having a composition composed of these elements alone or in combination are used. Use types. In order to obtain the target film, various film forming conditions are optimized and the electric power applied to each target is adjusted. Therefore, the multi-source sputtering method has an advantage over the single sputtering method in that the film composition can be precisely controlled and thin films having different compositions can be stacked under a wider film forming condition.

In particular, the multi-source sputtering method is promising for producing high quality multilayer films and multi-element thin films. As an example of such a multi-element thin film, a multi-component oxide thin film (for example,
_{Y 1 Ba 2 Cu 3 O y} , Pb 1 Zr 0. 5 Ti 0. 5 O y, SrTi
O ₃ etc.). In these thin films, the film composition greatly affects the crystal structure and the film characteristics, and the film composition is easily affected by the film forming conditions. The possible causes are as follows.

(1) Re-emission of deposited particles from a film due to impact of charged or neutral particles on a substrate. This phenomenon is caused by oxygen negative ions released from a target,
It depends on the energy level of oxygen, recoil argon, etc.

(2) Effect of type of sputtering gas For example, considering a mixed gas of argon gas and oxygen gas, the sputtering rate depends on the partial pressure ratio of argon gas and oxygen gas. This is because argon and oxygen have different degrees of target surface oxidation, and gas molecules have different masses. Furthermore, the difference in the degree of generation of intermediate products having a low adhesion probability in space varies depending on the type of gas, and the adhesion probability also changes.

(3) Change in adhesion probability with substrate temperature This is due to the temperature dependence of the vapor pressure of each substance deposited.
For example, when creating a Y ₁ Ba ₂ Cu ₃ O _y thin film, vapor pressure, various data - when compared with target material, Ba <CuO <
The relationship is Cu <BaO <Y <Y ₂ O ₃ , and since it is an oxide film, Cu is easily re-evaporated when the substrate temperature is raised.

In view of the above points, it is important for film reproducibility, composition controllability, and high quality to constantly monitor various film formation conditions during film formation and control them constantly. .
In particular, the substrate temperature is an important factor that greatly affects the film quality and film crystallinity.

[0008]

When heating a substrate in a multi-source sputtering apparatus, a mechanism for heating the substrate while moving it is necessary. Various structures are known as the structure of the rotation introducing shaft (the part that transmits the rotary motion from the drive source outside the vacuum chamber to the inside of the vacuum chamber) of the substrate heating moving mechanism. For example, there are a magnetic coupling type, a magnetic fluid type, an oil seal type and the like.

However, the magnetic coupling type cannot pass a thermocouple because of its structure, and the substrate temperature cannot be directly measured by the thermocouple. Further, since the magnetic fluid type uses a fluid, it cannot be used at a high temperature. On the other hand, in the oil seal type, since the thermocouple can be passed through the rotation introducing shaft, the thermocouple can be directly attached to the substrate. However, such a thermocouple mounting method is limited to a batch type apparatus having no substrate exchange mechanism. That is, in the case of the batch type, since the film forming chamber is set to the atmospheric pressure each time the substrate is replaced, the thermocouple can be directly attached to the substrate on which the film is formed. Further, in the case of this oil seal type, the substrate temperature during film formation is up to about 300 to 400 ° C.

By the way, in the multi-cathode sputtering apparatus having the substrate exchange mechanism capable of exchanging the substrate without exposing the target to the atmosphere, the oil shield as described above is used.
When the conventional substrate heating / moving mechanism having the rotary type rotation introducing shaft is used, there are the following problems in measuring the high temperature of the substrate.

A. Since the substrate temperature cannot be directly measured by the thermocouple, there are the following problems. (1) The growth temperature of the film cannot be identified because the substrate temperature for film formation is unknown. (2) When the substrate is heated, if the sputtering gas is introduced, the shutter is opened / closed, or the film deposition progresses, the substrate temperature is likely to change, but it is difficult to control the temperature due to the substrate temperature change. The temperature is not constant. (3) Even if a thermocouple is installed in a place different from the substrate to correct the temperature, the temperature coefficient differs depending on the substrate material, and a temperature calibration table is required for each substrate material to be deposited, which is not practical. .

B. When the substrate temperature is raised to a high temperature, the temperature of the substrate holder rises, causing the following problems. (1) The bearing of the rotation introducing shaft of the substrate heating / moving mechanism is thermally oxidized to cause defective rotation, which shortens the life of the rotation introducing shaft. (2) Thermal deformation occurs near the rotation introducing shaft of the substrate heating movement mechanism, and vacuum leakage occurs from this portion.

If the substrate temperature cannot be directly measured or cannot be kept constant as described above, the reproducibility, controllability and film quality of the film may be deteriorated as described above. Also,
Poor rotation and vacuum leakage due to thermal oxidation of the bearing of the substrate rotation introduction shaft deteriorates the quality of the film and shortens the life of the device.

An object of the present invention is to improve the reproducibility and controllability of the film composition by using a dummy substrate for measuring the substrate temperature so that the temperature of the substrate on which the film is formed is always constant. It is in. Further, another object of the present invention is to improve the vacuum sealing performance in the substrate rotation introducing shaft,
It is intended to reduce the heat transfer from the substrate holder part to the rotation introducing shaft to prolong the life of the substrate heating moving mechanism.

[0015]

A first aspect of the present invention is a sputtering apparatus for sputtering a plurality of targets while moving a substrate to deposit a film on the substrate, while the substrate is being heated and the target is targeted. A substrate heating moving mechanism that can move with respect to the get is provided, and the dummy substrate is attached to the substrate heating moving mechanism separately from the substrate, and the positional relationship between the substrate and the target and the dummy substrate and the target are provided. dummy and positional relationship such is geometrically equivalent - the substrate is disposed, the dummy - controls the substrate heating apparatus of the substrate heating moving mechanism based on the temperature of the substrate, the substrate heating moving mechanism
The substrate holder part, the substrate heating part and the substrate holder-rotating part
And the substrate holder-on the rotation introducing shaft of the rotating unit,
A plurality of seal devices separated in the axial direction are provided, and the plurality of seal devices are
Evacuate the space between seal devices or non-oxidize
It is characterized by creating a gas atmosphere. Non-oxidizing gas
As an inert gas such as argon or neon or nitrogen gas.
Can be used.

In the first invention, the dummy substrate is
It can be formed of the same material as the substrate on which the film is formed .

In the first aspect of the present invention, it is possible to provide a substrate exchange mechanism capable of exchanging substrates without exposing the target to the atmosphere .

Delete

In a second aspect based on the first aspect , a connecting member is interposed in a connecting portion between the substrate holder portion and the substrate holder-rotating portion, and the connecting member has a high melting point and a low thermal conductivity. It is characterized by being made of a material. In the present invention, the high melting point means 900 ° C. or higher, and the low thermal conductivity means 0.1 (cal · cm / cm 2 · sec · ° C.) or lower.

A third invention is characterized in that, in the second invention, the connecting member is made of ceramics. Ceramics include oxides, nitrides, borides,
Carbides can be used.

[0021]

According to the first aspect of the invention, the dummy substrate is provided at a position geometrically equivalent to the substrate on which the film is to be formed, and the substrate heating device is controlled by monitoring the temperature of the dummy substrate. Therefore, the temperature of the substrate on which the film is formed can be identified almost accurately, and precise temperature control can be performed. Also,
Since the substrate temperature can be constantly monitored and controlled before the film formation, the substrate temperature can be always kept constant by reliably responding to the substrate temperature fluctuation factors such as the introduction of the sputtering gas and the opening / closing of the shutter. In addition, the substrate holder
-Vacuum the space between the seals of the rotating part or
Is in a non-oxidizing gas atmosphere, so thermal oxidation of the bearing
Can be prevented. In addition, vacuum leakage from the rotary introduction shaft
Reduces the risk of.

Furthermore , a dummy made of the same material as the substrate on which the film is formed is used.
If it so that using a substrate, more precisely, it is possible to the same temperature control as the substrate for film formation.

[0023] In addition, other - a get to so that with a substrate exchange mechanism that can replace the substrate without being exposed to the air
Thus, the film forming substrates other than the dummy substrate can be exchanged without exposing the target to the atmosphere. As described above, the substrate temperature control system using the dummy substrate is particularly effective in the sputtering apparatus having the substrate exchange mechanism.

Delete

In the second and third aspects of the present invention, the connecting member between the substrate holder portion and the substrate holder-rotating portion is formed of a material having a high melting point and a low thermal conductivity, so that the substrate holder is changed from the substrate holder to the substrate holder. -Reduces heat transfer to the rotating part.

As described above, the first , second and third inventions contribute to prolonging the life of the substrate heating and moving mechanism.

[0027]

FIG. 1 is a plan sectional view of an embodiment of the sputtering apparatus of the present invention. The basic configuration of this device is 4
Cal with 6 targets and 6 substrates can be mounted
A cell type substrate holder is provided, and a substrate exchange mechanism is provided. The vacuum container 1 constitutes a film forming chamber, and inside the vacuum container 1 are four cathode electrodes 16 each provided with a target 17. Each cathode electrode 16 is connected to a high frequency power source 19 via an impedance matching circuit 18. At the center of the vacuum container 1 is a carousel-type substrate holder-5. This cylindrical drum type substrate holder
Six substrates 2 can be attached to the outer peripheral surface of 5. However, one of them is a dummy substrate. The substrate holder-5 is rotatable in the direction of arrow 39. A shutter 15 is arranged between the substrate holder 5 and the target 17. Inside the substrate holder-5 is a lamp heater 4 for heating the substrate. Therefore, the substrate 2 can be rotated while being heated.

FIG. 2 is a front sectional view of this sputtering apparatus. A main exhaust system (not shown) that exhausts air in the direction of arrow 11 through the main valve 10 below the vacuum container 1.
There are connected, the vacuum chamber 1 10 ^- can be kept ⁵ Pa or less vacuum state. A target shield 6 is provided in the vicinity of each target 17. The sputtering gas 9 is introduced into the film forming chamber from a ring-shaped pipe 40 through a mass flow meter (not shown).

The six substrates 2 are geometrically equivalent to each other in relation to the target 17, and five for film formation.
One substrate 2 and one dummy substrate 3 are substrate holders-5.
Attached to. The substrate holder-5 is rotationally driven by the substrate holder-rotating mechanism 8. Each substrate 2 is configured to pass in front of each target 17 at regular intervals. The substrate 2 can be moved to the substrate exchange chamber 14 in a vacuum state by using the substrate transfer mechanism 13 via the gate valve 12. A gate valve 12, a substrate exchange chamber 14,
The substrate transfer mechanism 13 constitutes a substrate exchange mechanism. Inside the substrate holder-5 (that is, the lamp heater 4
(Near) is measured by thermocouple 36.

FIG. 3 is an enlarged side sectional view showing a mounting portion of the dummy board. The dummy substrate 3 is attached to the substrate mounting plate 21, and the substrate mounting plate 21 is mounted to the substrate holder-5. Board mounting plate 21
The hole 41 is formed in the hole 41, and the thermocouples 7a and 7
Through b, the tip is bonded to the dummy substrate 3 by ceramer bond. The dummy substrate 3 and the substrate mounting plate 21 are heated by receiving the heat rays 20 from the lamp heater from the rear surface.
The bonding positions of the thermocouples 7a and 7b on the dummy substrate are not particularly limited, but they are preferably arranged at diametrically opposite positions. The power supply of the lamp heater can be controlled based on the temperature measured by either of the thermocouples 7a and 7b. In this embodiment, temperature control is performed by the PID control method. Furthermore, the in-plane temperature distribution of the dummy substrate 3 can be measured using this thermocouple and the other thermocouple.

FIG. 4 shows an example of the temperature measurement results when the substrate is heated using the above-mentioned substrate heating device. The measurement example of the lamp part temperature (measured by the thermocouple 36) and the dummy substrate temperature (measured by the thermocouple 7a) is shown. The higher the substrate temperature, the wider the temperature difference between the two, and when the lamp temperature is 800 ° C, there is a temperature difference of about 200 ° C.

FIG. 5 shows the lamp temperature and the dummy when the temperature is controlled so that the substrate temperature is kept constant at 600.degree.
The substrate temperature is shown. Generally, the substrate temperature is likely to change under various conditions such as gas introduction, discharge start, shutter opening, etc., but according to this measurement example, since the substrate temperature is directly measured by the thermocouple, -The substrate temperature is kept almost constant.

FIG. 6 is an enlarged front sectional view of the substrate holder-rotating mechanism 8. The support body 37 is the cooling water 22a, 22b.
Is water cooled by. Support body 37 and vacuum container 1
The space between them is vacuum-sealed by an O-ring 23. The rotation introducing shaft 5b is rotatably supported inside the support body 37. The rotation introducing shaft 5b has two bearings 24a, 2
It is rotatably supported by 4b and is vacuum-sealed by two oil seals 25a and 25b. As shown in a further enlarged view in FIG. 7, the vacuum seal between the space 42 between the two oil seals and the atmosphere is sealed in two stages. That is, basically, the upper oil seal 25a
And vacuum seal and then seal with O-rings 28, 29, 30.

Returning to FIG. 6, two thermocouples 7a and 7b pass through the inside of the rotation introducing shaft 5b. The atmosphere-side thermocouples 7a and 7b are connected to the slip ring 31, which prevents the thermocouples 7a and 7b from rotating on the atmosphere side. A gear 32 is fixed to the upper end of the rotation introducing shaft 5b, and the rotation of the motor 38 is transmitted to the rotation introducing shaft 5b via the gear 33 and the gear 32. The gear 33 has an arrow 34b
When rotated in the direction of, the rotation introducing shaft 5b rotates in the direction of the arrow 34a.

In such a substrate holder-rotation mechanism, the space 42 between the two oil seals 25a and 25b is formed.
Is evacuated through the valve 26 in the direction of arrow 27. Alternatively, instead of evacuation, the gas introduction system may be connected to the valve 26 to make the space 42 a non-oxidizing gas atmosphere such as an inert gas (argon gas or neon gas) or nitrogen gas. This allows the substrate holder
Even if heat was transferred to the rotation introducing shaft 5b when the No. 5 was heated, the bearings 24a and 24b were less likely to be oxidized, and rotation failure did not occur.

The lower end of the rotation introducing shaft 5b is fixed to the substrate holder 5 via a connecting member 35. Connection member 35
Is formed of ceramics (for example, alumina) having a high melting point and low thermal conductivity. A thermocouple 7 is provided at the center of the connecting member 35.
There is a hole through which a and 7b can pass. By interposing such a connecting member 35, the heat transferred to the rotation introducing shaft 5a is reduced even if the substrate holder 5 is heated to a high temperature. As the material of the connecting member 35, the same effect can be obtained by using ceramics such as nitrides, borides, and carbides as long as they are ceramics having a high melting point and low thermal conductivity in addition to alumina.

When the substrate heating and moving mechanism of this embodiment was used, the substrate temperature was 600 ° C. and the substrate rotation speed was 30 rp.
As m, a life of 2 years or more was achieved under the condition of using for 8 hours a day. On the other hand, when the conventional substrate heating moving mechanism was used, the life was only 2 months under the same operating conditions.

[0038]

By attaching a dummy substrate to the substrate holder of the substrate heating and moving mechanism and directly measuring the temperature of the dummy substrate to control the substrate temperature, one of the important factors of the film forming conditions is obtained. It is possible to accurately control the substrate temperature, and it is possible to easily obtain the reproducibility of the film quality of the manufactured film, the controllability of the film composition, and the high quality. In addition, the crystallization temperature when producing a new substance can be easily identified, and the physical properties of the new substance can be clarified.

Further, in the rotation introducing shaft of the substrate heating / moving mechanism, the space between the vacuum seal devices is evacuated or made into a non-oxidizing gas atmosphere to prevent thermal oxidation of the bearing and eliminate defective rotation. At the same time, vacuum leakage can be prevented. Furthermore, by interposing a connection member having a high melting point and low thermal conductivity between the rotation introducing shaft and the substrate holder, heat transferred from the substrate holder to the rotation introducing shaft can be reduced,
Various problems caused by thermal factors can be solved, and the life of the substrate heating and moving mechanism can be extended.

[Brief description of drawings]

FIG. 1 is a horizontal sectional view of an embodiment of the present invention.

FIG. 2 is a front sectional view of the device of FIG.

FIG. 3 is an enlarged side sectional view of a mounting portion of a dummy board.

FIG. 4 is a graph showing a relationship between a lamp temperature and a dummy-substrate temperature.

FIG. 5 is a graph when the temperature of the dummy substrate is controlled.

FIG. 6 is an enlarged front sectional view of a substrate holder-rotation mechanism.

FIG. 7 is a front cross-sectional view further enlarging a part of the substrate holder-rotation mechanism.

[Explanation of symbols]

2 Substrates for film formation 3 dummy board 4 lamp heater 5 Board holder 5b Rotation introduction shaft 7a, 7b thermocouple 8 Substrate holder-rotation mechanism 17 Target 24a, 24b bearing 25a, 25b oil seal 26 valves 35 Connection member

Continued front page       (56) References JP-A-62-196370 (JP, A)                 JP-A-3-223458 (JP, A)                 JP-A-2-97670 (JP, A)                 JP-A-62-107065 (JP, A)                 JP-A-60-110874 (JP, A)                 JP-A-3-111575 (JP, A)

Claims (3)

(57) [Claims] 1. A sputtering apparatus for depositing a film on a substrate by sputtering a plurality of targets while moving the substrate, wherein the substrate can be moved with respect to the target while heating the substrate. A heating movement mechanism is provided, and the dummy substrate is attached to the substrate heating movement mechanism separately from the substrate, and the positional relationship between the substrate and the target and the positional relationship between the dummy substrate and the target are geometrically equivalent. The dummy substrate is arranged so that the substrate heating device of the substrate heating moving mechanism is controlled based on the temperature of the dummy substrate, and the substrate heating moving mechanism is connected to the substrate holder part and the substrate heating part.
And the substrate holder-rotating part.
The rotary introduction shaft of the moving part is equipped with a plurality of seals that are separated in the axial direction.
Is installed, and the space between the plurality of seal devices is evacuated.
Or a non-oxidizing gas atmosphere . 2. The substrate holder part and the substrate holder
A connecting member is interposed in the connecting portion with the rotating portion, and this connecting portion
Characterized by forming the material with a high melting point and low thermal conductivity
The sputtering apparatus according to claim 1. 3. The connecting member is made of ceramics.
The sputtering apparatus according to claim 2, wherein: