Substrate processing device

Abstract

Disclosed is a substrate processing device capable of reducing damage of a peripheral member when a power supply member generates heat. The substrate processing device includes: a resistance heating element and a high-frequency electrode, to which a voltage is applied; a power supply member for a resistance heating element, and a power supply member for a high-frequency electrode, which supply power to the resistance heating element and the high-frequency electrode, respectively; a peripheral member disposed close to circumferences of these power supply members; and heat insulators arranged between the power supply members and the peripheral member and having heat resistance to a temperature at least higher than 250° C.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a substrate processing device which performs processing for a substrate (a silicon wafer).

2. Description of the Related Art

Heretofore, in a semiconductor manufacturing process and a liquid crystal device manufacturing process, a substrate processing device has been used. The substrate processing device is a device which mounts a substrate on a holding surface of a ceramic base and performs processing such as heating for the substrate. There is also a substrate processing device which functions as a plasma generating device.

In the case of using the substrate processing device also as the plasma generating device, there are provided an RF electrode (a high-frequency electrode), and a power supply member for the RF electrode (for example, a Ni rod as a metal conductor), which supplies a high-frequency current to the RF electrode (for example, refer to Japanese Patent Laid-Open Publication No. H11-26192 published in 1999).

When a high-frequency voltage is applied to the power supply member, owing to the skin effect, the current flows concentratedly through a surface of the power supply member (for example, the surface extends in a range from an outer circumferential surface of the power supply member to several-micron to several ten-micron deep), and the current hardly flows through a diametrical center of the power supply member.

Resistance of the power supply member is represented by the following equation (1). Since the current hardly flows through the diametrical center of the power supply member owing to the skin effect as described above, an apparent cross sectional area S is decreased. As a result, the resistance R rises. R=L/σS   (1)

where R: resistance;

• • L: length of power supply member;
  • σ: conductivity; and
  • S: cross-sectional area

Meanwhile, a heat generation amount of the power supply member is represented by the following equation (2). When the resistance R rises, the heat generation amount is also increased. W=RI²   (2)

where W: heat generation amount;

• • R: resistance; and
  • I: current

As described above, when the high-frequency voltage is applied to the power supply member, there has been a problem that the heat generation amount of the power supply member is increased owing to the skin effect.

Here, since many peripheral members arranged in the substrate processing device have complicated shapes, parts formed of resin in which processability is good and electrical insulating properties are also excellent are used as the peripheral members in many cases. However, since the peripheral members formed of the resin have relatively low heat resistance, there has been a possibility that the peripheral members are damaged by the high-temperature power supply member. A specific description will be made below.

Even in the case of heat-resistant resin said to have high heat resistance among the resins, a heat resistant temperature thereof is approximately 250° C. Therefore, when the high-frequency current and large power of an alternating current are supplied through the power supply member to the electrode of the substrate processing device, a temperature of the power supply member reaches 250° C. or more, and there has been a possibility that the peripheral members (parts) formed of the resin are damaged.

Moreover, there is a substrate processing device including a resistance heating element, and a power supply member for the resistance heating element, which supplies a voltage to the resistance heating element, and the power supply member concerned is directly connected to the resistance heating element. Therefore, in the case of heating the substrate processing device to a high temperature, the power supply member is also heated up to the high temperature owing to heat transfer, and there has been a possibility that the peripheral members formed of the resin are damaged.

In order to prevent such damage, it is conceivable to employ, as a material of the peripheral members, ceramics and the like which have the heat resistance and are less prone to cause thermal deformation. However, since it is difficult to process the ceramics, it is difficult to form the ceramics into the complicated shapes. Moreover, the ceramics are expensive. Therefore, it has been difficult to employ the ceramics.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a substrate processing device capable of reducing the damage of such a peripheral member when the power supply member generates heat.

In order to achieve the above-described object, a substrate processing device according to the present invention includes: a base having a member to be supplied with power; a power supply member which applies a voltage to the member to be supplied with power; a peripheral member disposed close to the power supply member; and a heat insulator disposed between the power supply member and the peripheral member and having heat resistance to a temperature at least higher than 250° C.

Since the heat insulator is provided in the substrate processing device according to the present invention, when the power supply member generates heat, heat transfer therefrom to the peripheral member can be decreased, and the damage to the peripheral member by the heat can be reduced to a large extent. Moreover, since the heat insulator has the heat resistance to the temperature at least higher than 250° C., the heat insulator exerts a heat insulating effect without being deteriorated even if the temperature of the power supply member rises to more than 250° C.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGURE is a cross-sectional view of a substrate processing device according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

A description will be made of an embodiment of the present invention.

FIGURE is a cross-sectional view showing a substrate processing device according to the embodiment of the present invention.

A substrate processing device 100 includes a ceramic base 20, a shaft 10, power supply members 11 and 16, and a peripheral member 14.

The ceramic base 20 is composed of AlN, SN, SiC, alumina, or the like, and formed to have a thickness of 0.5 to 30 mm. It is preferable that an outer shape of the ceramic base 20 be disc-like or polygonal.

Moreover, a surface of the ceramic base 20 is formed into a holding surface 20a. Then, in an inside of the ceramic base 20, a high-frequency electrode 21 is embedded on an upper side thereof, and a resistance heating element 22 is embedded below the high-frequency electrode 21. A power supply member 11 for a high-frequency electrode is coupled to the high-frequency electrode 21, and power supply members 16 for a resistance heating element are coupled to the resistance heating element 22. Thus, when a voltage is applied from the power supply members 16 for a resistance heating element to the resistance heating element 22, the resistance heating element 22 is heated up, and a substrate mounted on the holding surface 20a is subjected to a heating treatment by heat applied thereto. Note that the high-frequency electrode 21 and the resistance heating element 22, which are described above, are members to be supplied with power, which receive a supply of the power from the power supply members 11 and 16.

Moreover, the substrate processing device 100 functions also as a plasma processing device which generates plasma by applying a high-frequency voltage from the power supply members 16 for a resistance heating element to the high-frequency electrode 21.

On a back surface 20b of the ceramic base 20 which constitutes the substrate processing device 100, a shaft 10 which supports the ceramic base 20 is provided. The shaft 10 is formed into a hollow cylinder or the like, and formed of aluminum nitride, silicon nitride, aluminum oxide, or the like.

An upper end of the shaft 10 is coupled to the back surface 20b of the ceramic base 20 by integral coupling, seal coupling, and the like. Note that, in the case of performing the seal coupling, an O-ring, a metal packing, and the like are used. Note that, when a gas introduction passage is formed on the back surface 20b of the ceramic base 20, the above-described coupling is performed while maintaining air tightness of the gas introduction passage.

On an inner circumference side of the shaft 10, the power supply member 11 for a high-frequency electrode and the power supply members 16 for a resistance heating element, which are as described above, are arranged.

High-frequency power is supplied to the high-frequency electrode 21 from the power supply member 11 for a high-frequency electrode, and the high-frequency electrode 21 generates the plasma. A mesh shape, a plate shape, and the like can be employed as a shape of the high-frequency electrode 21. The high-frequency electrode 21 may be formed by printing a conductive paste on a base material. The high-frequency electrode 21 has conductivity, and for example, it is preferable to form the high-frequency electrode 21 of W, Mo, WMo, WC, or the like.

The resistance heating element 22 generates heat by receiving a supply of a current from the power supply members 16, and heats up the substrate mounted on the holding surface 20a.

A mesh shape, a coil shape, a plate shape, or the like can be employed as a shape of the resistance heating element 22. The resistance heating element 22 can be formed by printing a conductive paste on a base material. The resistance heating element 22 has conductivity, and for example, it is preferable to form the resistance heating element 22 of W, Mo, WMo, WC, or the like.

Moreover, the power supply member 11 for a high-frequency electrode is formed of Ni, Al, Cu, or an alloy containing these metals, and as a shape of the power supply member 11 concerned, various shapes can be employed, which include a rod shape (stick shape), a column shape, a cable shape, a plate shape, a cord shape, and a cylinder shape. A connection terminal is provided on an upper end of the power supply member 11 for a high-frequency electrode, and the connection terminal is coupled to the high-frequency electrode by crimping, welding, brazing, soldering, and the like.

Moreover, upper ends of the power supply members 16 for a resistance heating element are directly connected to the resistance heating element 22 by brazing, welding, eutectic bonding, crimping, fitting, screwing, and the like.

Then, outer circumferential surfaces of upper portions (specifically, portions from the back surface 20b of the ceramic base 20 to the peripheral member 14) of the power supply member 11 for a high-frequency electrode and the power supply members 16 for a resistance heating element are covered with electrical insulating pipes 15 as heat insulators with electrical insulating properties.

Outer circumferential surfaces of lower ends of the power supply members 11 and 16 are covered with heat insulators 12 formed into a pipe shape. Meanwhile, on an inner circumference side of a lower end of the shaft 10, the disc-like peripheral member 14 is provided, and on the peripheral member 14, insertion holes are formed. The power supply member 11 for a high-frequency electrode and the power supply members 16 for a resistance heating element, which are covered with the heat insulators 12, are inserted into the insertion holes of the peripheral member 14. As described above, the lower ends of the power supply members 11 and 16 are fitted to the peripheral member 14 through the heat insulators 12.

Hence, even in the case where the voltage is applied to the power supply members 11 and 16, and the power supply members 11 and 16 generate heat, a discharge of the heat to the peripheries thereof is decreased by the heat insulators 12. Accordingly, the damage of the peripheral member 14, which results from such heat generation, is decreased.

The heat insulators 12 have heat resistance to a temperature at least higher than 250° C., preferably, a temperature equal to or higher than 1000° C. According to this, even in the case where the voltage is applied to the power supply members 11 and 16, and the power supply members 11 and 16 are heated up to a temperature as high as approximately 250° C., transfer of the heat generated in the power supply members 11 and 16 to the peripheral member 14 is decreased efficiently, thus making it possible to restrict deformation of the peripheral member 14.

Moreover, if a heat resistant temperature of the heat insulators 12 is equal to or higher than 1000° C., even if a temperature of the power supply members 11 and 16 rises nearly to 1000° C., the heat insulators 12 can surely exert a heat insulating effect without being deformed, and so on.

Moreover, thermal conductivity of the heat insulators 12 is preferably 100 W/m·K or less, more preferably, 50 W/m·K or less. According to this, an amount of the heat transferred from the power supply members 11 and 16 to the peripheral member 14 can be reduced, thus making it possible to restrict the deformation of the peripheral member 14.

It is preferable that the heat insulators 12 be formed of ceramics. Specifically, it is preferable that the heat insulators 12 be formed of alumina, zirconia, aluminum nitride, or the like. According to this, the heat insulators 12 having high heat insulating properties and heat resistance can be formed.

It is preferable that each of the heat insulators 12 be formed into a cylinder shape with a thickness of 0.3 mm or more. Each of the heat insulators 12 is formed into the cylinder shape with a thickness of 0.3 mm or more, and thus breakage and the like thereof can be restricted while ensuring strength thereof.

Volume resistivity of the heat insulators 12 is preferably 10¹¹ Ω·cm or more, more preferably, 10¹⁴ Ω·cm or more. Moreover, it is preferable that the heat insulators 12 be electrical insulators having a withstand voltage of 2 kV or more. According to this, the heat insulators 12 reduce an amount of a current flowing from the power supply member 11 to the peripheral member 14 even if the temperature of the power supply member 11 rises, thus making it possible to operate the substrate processing device 100 appropriately, and to prevent the peripheral member 14 from generating the heat by the current.

Moreover, even if the peripheral member 14 is disposed adjacent to the power supply members 11 and 16 at an interval (distance) of 5 mm or less, since the heat insulators 12 are provided on the power supply members 11 and 16, the discharge of heat from the power supply members 11 and 16 to the peripheral member 14 is decreased, thus making it possible to reduce the damage owing to the heat transfer.

For example, a material of the peripheral member 14 is polytetrafluoroethylene (trade name: Teflon) as one of fluorine resins, high-performance thermoplastic resin, or the like, and the material can be processed into a complicated shape. Moreover, it is preferable that the peripheral member 14 have the electrical insulating properties.

As described above, the heat insulators 12 are provided between the peripheral member 14 and the power supply members 11 and 16, and thus the substrate processing device 100 can decrease the heat transfer from the power supply members 11 and 16 to the peripheral member 14 when the power supply members 11 and 16 generate the heat. Thus, it is made possible to provide a substrate processing device which reduces the damage to the peripheral member, which results from the heat generation of the power supply members 11 and 16.

Note that the present invention is not limited to the above-described embodiment, and various alterations are possible. For example, the substrate processing device 100 may also be the one in which the high-frequency electrode 21 and the resistance heating element 22 are not embedded in the ceramic base 20, or the one in which the shaft 10 is not provided.

EXAMPLES

A specific description will be made of the present invention through Reference examples and Examples.

Reference Example

First, a description will be made of Reference examples serving as the premise of the present invention prior to a description of Examples. In Reference examples, the distance between the power supply members and the peripheral member was changed as appropriate, and it was verified whether or not the thermal deformation occurred in the peripheral member. In Reference examples, though the substrate processing device shown in FIGURE was used, the heat insulators 12 were not provided for the power supply members.

A high-frequency voltage with a frequency of 13.56 MHz and power of 2000 W was applied to the power supply members for 40 minutes. Then, the temperature of the peripheral member was verified, and it was verified whether or not the thermal deformation occurred in the peripheral member. A thermal tape at a temperature of 250° was pasted to a region among regions of the peripheral member, which is the closest to the power supply member, and a change of color of the thermal tape was confirmed. Thus, the temperature of the peripheral member was measured. Moreover, it was visually determined whether or not the thermal deformation of the peripheral member occurred. Verification results of Reference examples are shown in Table 1.

[Table 1]

	TABLE 1
	REFERENCE	REFERENCE	REFERENCE	REFERENCE
	EXAMPLE 1	EXAMPLE 2	EXAMPLE 3	EXAMPLE 4
PERIPHERAL	MATERIAL	THERMOPLASTIC RESIN
MEMBER	MAXIMUM	250
	CONTINUOUS USE
	TEMPERATURE [° C.]
DISTANCE BETWEEN POWER SUPPLY	1	3	5	7
MEMBER AND PERIPHERAL MEMBER [mm]
TEMPERATURE OF PERIPHERAL MEMBER	>250	>250	>250	<250
[° C.]
THERMAL DEFORMATION	PRESENT	PRESENT	PRESENT	NONE (THERMAL
OF PERIPHERAL MEMBER				DEFORMATION IS
				PRESENT IN CLOSEST
				REGION TO POWER
				SUPPLY

As shown in Table 1, in Reference examples 1 to 4, a peripheral member was used, in which the material is the thermoplastic resin, and the maximum temperature (the maximum continuous use temperature) at which the peripheral member is continuously usable is 250° C.

Note that, in Reference examples 1 to 4, the distance between the power supply members and the peripheral member was set at 1 mm, 3 mm, 5 mm, and 7 mm, respectively.

A brief description will be made of the results of Reference examples.

While the temperature of the peripheral member rose more than 250° C. in Reference examples 1 to 3, the temperature of the peripheral member was lower than 250° C. in Reference example 4.

Moreover, in each of Reference examples 1 and 2, the thermal deformation occurred in the peripheral member, and the breakage occurred in the substrate processing device. In Reference example 3, though the thermal deformation occurred in the peripheral member, no breakage occurred in the substrate processing device.

In Reference example 4, though the temperature of the peripheral member was lower than 250° C., a capability to hold the power supply members by the peripheral member was decreased, and the power supply members were held in an inclined manner. A distance at which the inclined power supply members and the peripheral member came closest to each other was less than 5 mm, and in a region where the power supply members and the peripheral member came closest to each other, the thermal deformation occurred in the peripheral member.

From the results of Reference examples 1 to 4 described above, it was proven that there occurred the thermal deformation of the peripheral member, the breakage of the substrate processing device, and the like owing to the heat generation of the power supply members when the peripheral member was arranged adjacent to the power supply members at the distance of 5 mm or less.

Examples

Subsequently, a description will be made of Examples according to the present invention. In Examples, the substrate processing device used in Reference examples described above was used, and for the power supply members of the substrate processing device, the heat insulators were provided. Specifically, the thermoplastic resin in which the maximum continuous use temperature is 250° C. was used for the peripheral member, and the distance between the power supply members and the peripheral member was set at 3 mm.

In Examples, the heat insulators composed of three types of materials were used, and the temperature of the peripheral member, the thermal deformation of the peripheral member, and the thermal deformation of the heat insulators were verified. Results of the verification are shown below in Table 2.

[Table 2]

	TABLE 2
			COMPARATIVE
	EXAMPLE 1	EXAMPLE 2	EXAMPLE 1
HEAT	MATERIAL	Al2O3	AIN	POLYTETRA-
INSULATING		CERAMICS	CERAMICS	FLUOROETHYLENE
MATERIAL	THICKNESS OF HEAT	1	1	1
	INSULATING MATERIAL [mm]
	MAXIMUM CONTINUOUS	>1000	>1000	250
	USE TEMPERATURE [° C.]
	THERMAL CONDUCTIVITY	35	100	0.25
	[W/m · k]
	VOLUME RESISTIVITY	>1E+16	1E+15	>1E+18
	(ROOM TEMPERATURE) [Ω · cm]
	WITHSTAND VOLTAGE [kV/mm]	>2	>2	>2
TEMPERATURE OF PERIPHERAL MATERIAL [° C.]	<250	<250	<250
THERMAL DEFORMATION OF PERIPHERAL MEMBER	NONE	NONE	NONE
THERMAL DEFORMATION OF HEAT INSULATING MATERIAL	NONE	NONE	PRESENT
EFFECT	◯	◯	X

The heat insulators were formed into a cylinder shape with a thickness of 1 mm. For the materials of the heat insulators in Examples 1 and 2 and Comparative example 1, Al₂O₃, AlN, and polytetrafluoroethylene (trade name: Teflon) were used, respectively.

The high-frequency voltage with a frequency of 13.56 MHz and power of 2000 W was applied to the power supply members for 40 minutes. Then, the temperature of the peripheral member, the thermal deformation of the peripheral member, and the thermal deformation of the heat insulators were verified.

The temperature and thermal deformation of the peripheral member were verified in the same way as in the case of Reference examples described above. Moreover, the thermal deformation of the heat insulators was visually confirmed.

In Examples 1 and 2, no thermal deformation occurred in both of the peripheral member and the heat insulators, or no malfunction or the like of the substrate processing device occurred. However, in Comparative example 1, though no thermal deformation of the peripheral member occurred, the heat insulators were thermally deformed and inhibited thermal expansion of the power supply members. Accordingly, the malfunction occurred in the substrate processing device.

From the results of Examples 1 and 2 and Comparative example 1, which are as described above, the following was proven. Specifically, by arranging the heat insulators provided with the heat resistance to the temperature higher than 250° C. between the peripheral member and the power supply members, the heat transfer from the power supply members to the peripheral member can be decreased, thus making it possible to reduce the damage and the like of the peripheral member. Moreover, it was proven that the damage and the like of the substrate processing device can be thus prevented.

Claims

1. A substrate processing device, comprising: a base including a member to be supplied with power; a power supply member which applies a voltage to the member to be supplied with power in the base; a peripheral member disposed close to the power supply member; and a heat insulator disposed between the power supply member and the peripheral member and having heat resistance to a temperature at least higher than 250° C.

2. The substrate processing device according to claim 1, wherein the member to be supplied with power is at least a resistance heating element or a high-frequency electrode.

3. The substrate processing device according to claim 1, wherein thermal conductivity of the heat insulator is 50 W/m·K or less.

4. The substrate processing device according to claim 1, wherein the heat insulator is an electrical insulator.

5. The substrate processing device according to claim 4, wherein the electrical insulator is ceramics.

6. The substrate processing device according to claim 1, wherein at least a part of the peripheral member is disposed adjacent to the power supply member at a distance of 5 mm or less.

7. The substrate processing device according to claim 1, wherein a withstand voltage of the heat insulator is 2 kV or more.