JP2001168177A - Ceramic board for manufacturing and inspecting semiconductor device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ceramic board for a semiconductor manufacturing apparatus capable of preventing warpage in the ceramic board, and damage to a silicon wafer mounted on the ceramic board due to warpage. SOLUTION: The ceramic board for manufacturing and inspecting a semiconductor wafer, or keeps a predetermined distance from its surface. A surface roughness of the ceramic board is Rmax=0.1 to 250 μm on the basis of JIS R 0601. The surface roughness on the mounting and supporting surface of the ceramic board is the same as that of its opposite side, or the difference of the surface roughness is not more than 50% between the mounting and support surface of the board and its opposite side surface.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention mainly relates to semiconductor manufacturing and
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ceramic plate used for an inspection device, and more particularly to a ceramic plate for a semiconductor manufacturing / inspection device on which a large silicon wafer can be mounted and the wafer is not damaged.

[0002]

2. Description of the Related Art Semiconductors are extremely important products required in various industries.
The silicon wafer is manufactured by slicing a silicon single crystal to a predetermined thickness to produce a silicon wafer, and then forming various circuits and the like on the silicon wafer. In such a semiconductor chip manufacturing process, for example, a semiconductor manufacturing / inspection apparatus using a ceramic substrate as a base, such as an electrostatic chuck, a hot plate, a wafer prober, and a susceptor, has been actively used.

As such a semiconductor manufacturing / inspection apparatus,
For example, Japanese Patent No. 2587289, JP-A-10-7
No. 2260 discloses a ceramic substrate used for these applications.

The ceramic substrates disclosed in the above publications have a diameter of about 6 inches (150 mm) or a thickness of 8 mm or more. However, with the recent increase in the size of silicon wafers, ceramic substrates having a diameter of 8 inches or more have been required.

[0005] In the process of manufacturing a silicon wafer, it is necessary to use a ceramic substrate in which a heating element is buried inside for heating, and further, in order to reduce the heat capacity and improve the temperature followability. It has become necessary to reduce the thickness to less than 10 mm. Further, Japanese Patent Application Laid-Open
According to Japanese Patent Publication No. 280462, in this ceramic heater, a surface on which a silicon wafer is mounted or held at a predetermined interval (hereinafter, referred to as a wafer mounting / holding surface) is roughened in accordance with JIS R0601. Degree Rmax
= 2 μm or less, and the surface roughness of the opposite side is set to a value sufficient to cause irregular reflection of heat rays, that is, Rmax =
It is adjusted to 2 to 200 μm.

[0006]

However, when a ceramic heater in which a heating element is formed on a large and thin ceramic substrate subjected to such a roughening treatment is used, there is a problem that warpage occurs in a high temperature region. Therefore, when the cause of such a problem was investigated, it was found that the mechanism was as follows.

In this ceramic heater, the wafer mounting
The opposite side has a greater surface roughness than the holding surface. For this reason, when the Young's modulus decreases at a high temperature, the surface opposite to the wafer mounting / holding surface having a large roughness becomes slightly easier to elongate, thereby causing warpage. Also, if the surface roughness of both main surfaces of the ceramic substrate is too large, the wafer mounting / holding surface is more likely to shrink even if the surface roughness is the same for the wafer mounting / holding surface and the opposite side surface. On the other hand, if the surface roughness is made extremely small and flattening is required, the conditions for polishing and blasting must be severe. Is left at a high temperature, and consequently, warpage is likely to occur.

[0008]

Means for Solving the Problems The inventors of the present invention have conducted various studies to solve the problem of warpage of the ceramic substrate, and as a result, have determined that the surface roughness of both main surfaces of the ceramic substrate is within a predetermined range. By adjusting the difference in surface roughness between the wafer mounting / holding surface and the opposite side surface to 50% or less, it is possible to prevent the ceramic substrate from warping. The present invention has been completed.

That is, the present invention relates to a ceramic plate for a semiconductor manufacturing / inspection apparatus for mounting a semiconductor wafer on a surface of a ceramic substrate or holding the semiconductor wafer at a predetermined distance from the surface of the ceramic substrate. The surface roughness of the substrate based on JIS R 0601 is Rm
ax = 0.1 to 250 μm, and the surface roughness of the wafer mounting / holding surface of the ceramic substrate is the same as the surface roughness of the opposite side, or the surface of the wafer mounting / holding surface A ceramic plate for a semiconductor manufacturing / inspection apparatus, wherein the difference between the roughness and the surface roughness of the opposite side is 50% or less. In the above-mentioned ceramic plate for a semiconductor manufacturing / inspection apparatus, it is desirable that the ceramic substrate has a disk shape and has a diameter of 200 mm or more and a thickness of 50 mm or less.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION In a ceramic plate for a semiconductor manufacturing / inspection apparatus according to the present invention, a semiconductor wafer is mounted on a surface of a ceramic substrate or a semiconductor wafer is held at a predetermined distance from the surface of the ceramic substrate. In a ceramic plate for a semiconductor manufacturing / inspection device, the J
The surface roughness based on IS R 0601 is Rmax = 0.
1 to 250 μm, and the surface roughness of the wafer mounting / holding surface of the ceramic substrate and the surface roughness of the opposite side are the same, or the surface roughness of the wafer mounting / holding surface and the The difference from the surface roughness of the opposite side surface is 50% or less.

In this specification, the difference in surface roughness is defined by the following (1)
It means the value calculated by the formula. Surface roughness difference (%) = [(large surface roughness−small surface roughness) / large surface roughness] × 100 (1) Therefore, in the ceramic plate for a semiconductor manufacturing / inspection apparatus of the present invention, Alternatively, the wafer mounting / holding surface may have a higher surface roughness, and the opposite surface of the wafer mounting / holding surface may have a higher surface roughness.

In the present invention, first, the JI of the ceramic substrate is
The surface roughness based on SR0601 is Rmax = 0.1 to
Since the thickness is adjusted to 250 μm, the problem described in the section of “Prior Art”, that is, the wafer mounting / holding surface does not easily shrink and no stress remains on the surface. Further, the surface roughness of the wafer mounting / holding surface and the surface roughness of the opposite side are the same, or the difference between the surface roughness of the wafer mounting / holding surface and the surface roughness of the opposite side is different. Since the surface roughness is adjusted to 50% or less, there is no occurrence of warpage due to an excessively large difference in surface roughness.

In particular, the difference in surface roughness is optimally 20% or less. By making the difference in surface roughness 20% or less, the diameter 20
The warpage of a disc ceramic substrate of 0 mm or less can be reduced to 5 μm or less, improving the heating characteristics of semiconductor wafers, eliminating inspection errors of wafer probers, and improving the chucking force of electrostatic chucks. Because it becomes. Therefore, even if a silicon wafer or the like is placed on the ceramic plate for a semiconductor manufacturing / inspection apparatus and heated, the silicon wafer is not damaged due to the warpage.

The ceramic substrate used in the present invention preferably has a diameter of 200 mm or more and a thickness of 50 mm or less. This is because a semiconductor wafer having a diameter of 8 inches or more is mainly used, and a large size is required.

Further, a ceramic substrate having a diameter of 8 inches or more is likely to be warped at a high temperature, and has such a size that the structure of the present invention works effectively. More preferably, the diameter of the ceramic substrate is 12 inches (300 mm) or more. This is because the size will be the mainstream of next-generation semiconductor wafers.

The reason why the thickness of the ceramic substrate is preferably 50 mm or less is that if the thickness exceeds 50 mm, the heat capacity of the ceramic substrate becomes large, and if a temperature control means is provided for heating and cooling, the temperature followability is reduced. Because.

In addition, a thin ceramic substrate having a thickness of 50 mm or less is more likely to be warped at a high temperature, and the structure of the present invention works effectively. The thickness of the ceramic substrate is 5
mm or less is more desirable. If the thickness exceeds 5 mm, the heat capacity increases, and the temperature controllability and the temperature uniformity of the wafer mounting / holding surface deteriorate.

In the ceramic plate of the present invention, 25 to 800
It is desirable to use a ceramic having a Young's modulus of 280 GPa or more in the temperature range up to ° C. Such a ceramic is not particularly limited, and examples thereof include a nitride ceramic and a carbide ceramic.

If the Young's modulus is less than 280 GPa, the rigidity is too low, so that it is difficult to reduce the amount of warpage during heating.

Examples of the nitride ceramic include aluminum nitride, silicon nitride, and boron nitride.
Examples of the carbide ceramic include silicon carbide, zirconium carbide, titanium carbide, tantalum carbide, and tungsten carbide. When the above-mentioned aluminum nitride is used, a composition in which the amount of aluminum nitride exceeds 50% by weight is preferably aluminum nitride. Other ceramics used in this case include, for example, alumina, sialon, silicon carbide, silicon nitride and the like.

The Young's modulus of the ceramic substrate is controlled by mixing or laminating two or more types of ceramics, and by adding, for example, an alkali metal, an alkaline earth metal, a rare earth metal, or carbon. can do. As the alkali metal and alkaline earth metal, Li, Na, Ca, Rb and the like are desirable,
Y is desirable as the rare earth metal. As the carbon, either amorphous or crystalline carbon can be used. Further, the content of carbon is desirably 100 to 5000 ppm. This is because such a content makes it possible to blacken the ceramic plate.

In the present invention, a conductor layer is provided inside the ceramic substrate, and this conductor layer can function as, for example, a heating element, a guard electrode, a ground electrode, an electrostatic electrode, and the like. In addition, a conductor layer is provided on the surface of the ceramic substrate, and this conductor layer can function as, for example, a heating element, a chuck top electrode, or the like. Further, a plurality of conductor layers such as a heating element, a guard electrode, and a ground electrode can be provided inside the ceramic substrate. Also,
When an electrostatic electrode is provided, it functions as an electrostatic chuck.

Examples of the material forming the conductor layer include a metal sintered body, a non-sintered metal body, and a sintered body of a conductive ceramic. As a raw material of the metal sintered body and the non-sinterable metal body, for example, a high melting point metal or the like can be used. As the high melting point metal, for example,
Tungsten, molybdenum, nickel and indium, and the like. These may be used alone or 2
More than one species may be used in combination. Examples of the conductive ceramic include carbides of tungsten and molybdenum.

The ceramic plate provided with such a heating element, a guard electrode, a ground electrode, and the like can be used as, for example, a hot plate (ceramic heater), an electrostatic chuck, a wafer prober, and the like.

FIG. 1 is a plan view schematically showing an example of a ceramic heater which is an embodiment of a ceramic plate for a semiconductor manufacturing / inspection apparatus of the present invention. FIG. 2 is a schematic view showing a part of the ceramic heater. It is a partial expanded sectional view shown typically.
The ceramic substrate 11 is formed in a disk shape, and the heating element 12 is concentrically formed on the bottom surface of the ceramic substrate 11 in order to heat the wafer mounting / holding surface of the ceramic substrate 11 so that the entire temperature becomes uniform. It is formed in a pattern of a shape.

The heating elements 12 are connected to form a single line with a pair of double concentric circles close to each other, and terminal pins 13 serving as input / output terminals are connected to both ends thereof. I have. Further, a through hole 15 for inserting the support pin 16 is formed in a portion near the center, and further,
A bottomed hole 14 for inserting a temperature measuring element is formed.

Further, as shown in FIG.
Is capable of placing the silicon wafer 19 thereon and moving it up and down, thereby transferring the silicon wafer 19 to a carrier (not shown) or receiving the silicon wafer 19 from the carrier. Can be.
The heating element 12 may be formed in the ceramic substrate 11 at the center thereof or at a position eccentric to the wafer mounting / holding surface from the center.

As the pattern of the heating element 12, for example,
Concentric circles, spirals, eccentric circles, bending lines, etc.
From the point that the temperature of the entire heater plate can be made uniform,
A concentric one as shown in FIG. 1 is preferred.

In order to form the heating element 12 inside or on the bottom of the ceramic substrate, it is desirable to use a conductive paste made of metal or conductive ceramic. That is, when a heating element is formed inside a ceramic substrate, a heating element is manufactured by forming a conductor paste layer on a green sheet, and then laminating and firing the green sheet. On the other hand, when a heating element is formed on the surface,
After baking to produce a ceramic substrate, a conductor paste layer is formed on the surface of the ceramic substrate, and baking is performed to produce a heating element.

The conductive paste is not particularly limited, but preferably contains not only metal particles or conductive ceramic for ensuring conductivity, but also resin, solvent, thickener and the like.

As the metal particles, for example, noble metals (gold, silver, platinum, palladium), lead, tungsten, molybdenum, nickel and the like are preferable. These may be used alone or in combination of two or more. This is because these metals are relatively hard to oxidize and have a resistance value sufficient to generate heat.

As the conductive ceramic, for example,
Tungsten, molybdenum carbide and the like can be mentioned.
These may be used alone or in combination of two or more. The metal particles or conductive ceramic particles preferably have a particle size of 0.1 to 100 μm. If it is too fine, less than 0.1 μm, it is liable to be oxidized, while if it exceeds 100 μm, sintering becomes difficult and the resistance value becomes large.

Even if the shape of the metal particles is spherical,
It may be scaly. When these metal particles are used, they may be a mixture of the above-mentioned spheres and the above-mentioned flakes. When the metal particles are flakes or a mixture of spheres and flakes, the metal oxide between the metal particles can be easily held, and the adhesion between the heating element 12 and the nitride ceramic or the like can be improved. And it is advantageous because the resistance value can be increased.

As the resin used for the conductor paste,
For example, an epoxy resin, a phenol resin, and the like can be given. Examples of the solvent include isopropyl alcohol. Examples of the thickener include cellulose and the like.

As described above, the conductive paste is
It is desirable that a metal oxide be added to the metal particles and that the heating element 12 be formed by sintering the metal particles and the metal oxide. As described above, by sintering the metal oxide together with the metal particles, the nitride ceramic as the ceramic substrate and the metal particles can be adhered to each other.

It is not clear why mixing the above metal oxide improves the adhesion with nitride ceramics and the like, but the surface of metal particles and the surface of nitride ceramic are
It is considered that the oxide film is slightly oxidized to form an oxide film, and the oxide films are sintered and integrated via the metal oxide, so that the metal particles adhere to the nitride ceramic or the like.

As the metal oxide, for example, oxidized
Lead, zinc oxide, silica, boron oxide (B _Two O_Three ), Al
Selected from the group consisting of Mina, Yttria and Titania
At least one is preferred. These oxides are exothermic
The metal particles can be nitrided without increasing the resistance of the body 12.
Because it can improve the adhesion with the ceramic
is there.

The ratio of the above-mentioned lead oxide, zinc oxide, silica, boron oxide (B ₂ O ₃ ), alumina, yttria, and titania is as follows: 1-10, silica 1-30, boron oxide 5-50, zinc oxide 20-70, alumina 1
-10, yttria 1-50, titania 1-50, and the total is preferably adjusted within a range not exceeding 100 parts by weight. By adjusting the amounts of these oxides in these ranges, the adhesion to the nitride ceramic can be particularly improved.

The amount of the metal oxide added to the metal particles is preferably 0.1% by weight or more and less than 10% by weight. The heating element 1 is formed by using the conductor paste having such a configuration.
2 is preferably from 1 to 45 mΩ / □. If the area resistivity exceeds 45 mΩ / □, the amount of heat generated becomes too large with respect to the applied voltage, and it is difficult to control the amount of heat generated in the ceramic substrate 11 provided with the heating element 12 on the surface. The amount of metal oxide added is 1
If the content is 0% by weight or more, the sheet resistivity exceeds 50 mΩ / □, the amount of generated heat becomes too large, temperature control becomes difficult, and the uniformity of the temperature distribution decreases.

When the heating element 12 is formed on the surface of the ceramic substrate 11, it is desirable that a metal coating layer 12a as shown in FIG. This is to prevent the internal metal sintered body from being oxidized to change the resistance value. Metal coating layer 12a to be formed
Is preferably 0.1 to 10 μm.

The metal used for forming the metal coating layer 12a is not particularly limited as long as it is a non-oxidizing metal. Specifically, for example, gold, silver, palladium, platinum,
Nickel and the like can be mentioned. These may be used alone or in combination of two or more. Among these,
Nickel is preferred.

In the present invention, a thermocouple can be embedded in a ceramic substrate as needed. This is because the temperature of the heating element can be measured by a thermocouple, and the temperature and the amount of current can be changed based on the data to control the temperature.
The size of the joining portion of the metal wires of the thermocouple is equal to or larger than the element diameter of each metal wire.
5 mm or less is preferable. With such a configuration, the heat capacity of the junction is reduced, and the temperature is accurately and quickly converted to a current value. For this reason, the temperature controllability is improved and the temperature distribution on the heated surface of the wafer is reduced. As the thermocouple, for example, JIS-C-160
2 (1980), K-type, R-type, B-type
Type, S type, E type, J type, and T type thermocouples.

Next, a method of manufacturing a ceramic plate for a semiconductor manufacturing / inspection apparatus according to the present invention will be described. First, a method for manufacturing a ceramic plate in which the heating element 12 is formed on the bottom surface of the ceramic substrate 11 shown in FIG. 1 will be described.

(1) Preparation of Ceramic Plate A slurry is prepared by blending a sintering aid such as yttria or a binder as necessary with the above-described nitride ceramic such as aluminum nitride, and then spray-drying the slurry. The resulting granules are put into a mold or the like and pressed into a plate or the like to form a green body.

Next, if necessary, a portion serving as a through hole 15 for inserting a support pin 16 for supporting a silicon wafer and a bottomed hole 14 for embedding a temperature measuring element such as a thermocouple are formed in the formed body. Is formed.

Next, the formed body is heated, fired and sintered to produce a ceramic plate. After that, the ceramic substrate 11 is manufactured by processing into a predetermined shape, but may be a shape that can be used as it is after firing. By performing heating and firing while applying pressure, it is possible to manufacture a ceramic substrate 11 having no pores. Heating and firing may be performed at a temperature equal to or higher than the sintering temperature.

(2) Step of Printing Conductive Paste on Ceramic Substrate The conductive paste is generally a high-viscosity fluid composed of metal particles, resin and solvent. The conductor paste is printed on a portion where the heating element is to be provided by screen printing or the like to form a conductor paste layer. Since the heating element needs to keep the entire temperature of the ceramic substrate at a uniform temperature, it is desirable to print the heating element in a concentric pattern as shown in FIG. The conductor paste layer is desirably formed so that the cross section of the heating element 12 after firing has a rectangular and flat shape.

(3) Firing of the conductive paste The conductive paste layer printed on the bottom surface of the ceramic substrate 11 is heated and fired to remove the resin and the solvent, and sinter the metal particles.
The heating element 12 is formed. The heating and firing temperature is 500 to 1
000 ° C. is preferred. If the above-described metal oxide is added to the conductor paste, the metal particles, the ceramic substrate and the metal oxide are sintered and integrated, so that the adhesion between the heating element and the ceramic substrate is improved.

(4) Formation of Metal Coating Layer It is desirable to provide a metal coating layer 12a on the surface of the heating element 12 (see FIG. 2). The metal coating layer 12a can be formed by electrolytic plating, electroless plating, sputtering, or the like, but in consideration of mass productivity, electroless plating is optimal.

(5) Attachment of Terminals and the Like An external terminal 13 for connection to a power supply is attached to the end of the pattern of the heating element 12 by soldering. In addition, a thermocouple is inserted into the bottomed hole 14 and sealed with a heat-resistant resin such as polyimide or ceramic to obtain a ceramic heater 10.

Next, a method of manufacturing a ceramic plate having a heating element formed inside a ceramic substrate will be described. (1) Step of Producing Ceramic Substrate First, a nitride ceramic powder is mixed with a binder, a solvent, and the like to prepare a paste, and a green sheet is produced using the paste. As the above-mentioned ceramic powder, aluminum nitride or the like can be used, and if necessary,
A sintering aid such as yttria may be added. The amount of yttria is preferably at least 5% by weight. This is because 1 wt% or more of yttrium can be left in the sintered body, and the Young's modulus can be adjusted to 280 GPa or more in a temperature range of 25 to 800 ° C. 1 yttrium residue
If the weight is less than 280 GP at around 25 ° C.
a is less than a.

The binder is preferably at least one selected from an acrylic binder, ethyl cellulose, butyl cellosolve, and polyvinyl alcohol.
Further, as the solvent, at least one selected from α-terpineol and glycol is desirable.

A paste obtained by mixing these is formed into a sheet by a doctor blade method to produce a green sheet. The thickness of the green sheet is preferably 0.1 to 5 mm. Next, in the obtained green sheet, if necessary, a portion serving as a through hole for inserting a support pin for supporting a silicon wafer, and a portion serving as a bottomed hole for embedding a temperature measuring element such as a thermocouple. Then, a portion serving as a through hole for connecting the heating element to an external end pin is formed. The above processing may be performed after forming a green sheet laminate described later.

(2) Step of Printing Conductive Paste on Green Sheet A conductive paste containing a metal paste or a conductive ceramic is printed on the green sheet. These conductive pastes contain metal particles or conductive ceramic particles. The average particle diameter of the tungsten particles or molybdenum particles is preferably from 0.1 to 5 μm. If the average particle size is less than 0.1 μm or more than 5 μm, it is difficult to print the conductive paste.

As such a conductive paste, for example, 85 to 87 parts by weight of metal particles or conductive ceramic particles; 1.5 to 10 parts by weight of at least one kind of binder selected from acrylic, ethyl cellulose, butyl cellosolve, and polyvinyl alcohol And a composition (paste) obtained by mixing 1.5 to 10 parts by weight of at least one solvent selected from α-terpineol and glycol.

(3) Green Sheet Laminating Step Green sheets on which the conductor paste is not printed are laminated above and below the green sheet on which the conductor paste is printed.
At this time, the number of green sheets stacked on the upper side is made larger than the number of green sheets stacked on the lower side, and the formation position of the heating element is eccentric toward the bottom. Specifically, the number of stacked green sheets on the upper side is preferably 20 to 50, and the number of stacked green sheets on the lower side is preferably 5 to 20.

(4) Step of firing green sheet laminate The green sheet laminate is heated and pressed to sinter the green sheet and the internal conductive paste. The heating temperature is preferably from 1000 to 2000 ° C.,
100-200 kg / cm ² is preferred. Heating is performed in an inert gas atmosphere. As the inert gas, for example,
Argon, nitrogen and the like can be used.

After firing, a bottomed hole for inserting a temperature measuring element may be provided. The bottomed hole can be formed by performing blasting such as drilling or sand blasting after surface polishing. Also, connect the terminal to the through hole to connect with the internal heating element,
Heat and reflow. The heating temperature is preferably from 90 to 110 ° C. in the case of the soldering treatment, and is preferably from 900 to 1100 ° C. in the case of the treatment with the brazing material. Further, a thermocouple or the like as a temperature measuring element is sealed with a heat-resistant resin to form a ceramic heater.

[0059]

The present invention will be described in more detail below. (Example 1) Ceramic heater (1) 100 parts by weight of aluminum nitride powder (manufactured by Tokuyama Corporation, average particle size: 1.1 μm), yttria (average particle size: 0.1 μm)
4 μm) 4 parts by weight, acrylic binder 11.5 parts by weight,
Using a paste obtained by mixing 0.5 parts by weight of a dispersant and 53 parts by weight of alcohol composed of 1-butanol and ethanol, the mixture was molded by a doctor blade method to a thickness of 0.4.
A 7 mm green sheet was obtained.

(2) Next, the green sheet is heated to 80 ° C.
After drying for 5 hours, punch 1.8m in diameter
m, 3.0 mm and 5.0 mm through holes were respectively formed. These through holes are a portion to be a through hole for inserting a support pin for supporting the silicon wafer, a portion to be a through hole, and the like. (3) 100 parts by weight of tungsten carbide particles having an average particle diameter of 1 μm, 3.0 parts by weight of an acrylic binder, α-
A conductive paste A was prepared by mixing 3.5 parts by weight of a terpineol solvent and 0.3 parts by weight of a dispersant.

Tungsten particles 10 having an average particle diameter of 3 μm
A conductive paste B was prepared by mixing 0 parts by weight, 1.9 parts by weight of an acrylic binder, 3.7 parts by weight of an α-terpineol solvent and 0.2 parts by weight of a dispersant.

The conductive paste A was printed on a green sheet by screen printing to form a conductive paste layer for a heating element. The printing pattern was a concentric pattern as shown in FIG. On the green sheet after the above-mentioned processing, 37 sheets of unprinted green sheets are laminated on the upper side (heating surface) and 13 sheets on the lower side.
The laminated body was produced by integrating under a pressure of g / cm ² . In addition, the conductive paste B was filled in the through-hole portion to be a through-hole.

(4) Next, the obtained laminate was degreased in nitrogen gas at 600 ° C. for 5 hours, and at 1890 ° C. under a pressure of 150 ° C.
It was hot-pressed at kg / cm ² for 10 hours to obtain an aluminum nitride plate having a thickness of 3 mm. This was cut into a 300 mm disk, and a ceramic heater having a heating element with a thickness of 6 μm and a width of 10 mm was formed therein. Then, sand blasting was performed by spraying SiC having an average particle diameter of 2.5 μm on both surfaces, and the wafer was mounted. The surface roughness of the mounting / holding surface is JIS B
0601 Rmax = 2 μm, and the surface roughness of the opposite side is R
max = 2.3 μm. The size of the through hole was 0.2 mm in diameter and 0.2 mm in depth.

(5) Next, the plate-like body obtained in the above (4) is polished with a diamond grindstone, and a mask is placed thereon.
A bottomed hole 14 for a thermocouple was provided on the surface by blasting with SiC or the like.

(6) Further, the diameter is 5 m by drilling.
m, and a blind hole having a depth of 0.5 mm was formed.
Using gold brazing made of an Au alloy (Au: 81.5% by weight, Ni: 18.4% by weight, impurities: 0.1% by weight), 9
After heating and reflow at 70 ° C., an external terminal made of Kovar was connected. The external terminals are supported and connected by three metal layers made of tungsten. (7) Next, a plurality of thermocouples for temperature control were embedded in the bottomed holes, and the manufacture of the ceramic heater was completed.

Example 2 (1) Aluminum Nitride Powder (Average Particle Size: 1.1 μm)
100 parts by weight, yttria (average particle size: 0.4 μm) 4
The composition consisting of parts by weight, 12 parts by weight of an acrylic binder and alcohol was spray-dried to prepare a granular powder.

(2) Next, the granular powder was placed in a mold and formed into a flat plate to obtain a formed product (green).

(3) The processed form is processed by 180
Hot pressing was performed at 0 ° C. under a pressure of 200 kg / cm ² to obtain a 3 mm-thick aluminum nitride plate. Next, a disk having a diameter of 300 mm is cut out from the plate and subjected to sandblasting in which alumina particles having an average particle diameter of 5 μm are sprayed on both surfaces, and the surface roughness of the wafer mounting / holding surface is determined according to JIS B0601 Rmax. = 7 µm, and the surface roughness of the opposite side surface was Rmax = 7.5 µm. Further, a drilling is performed on the plate-like body, and a portion serving as a through hole 15 for inserting a support pin of a semiconductor wafer and a portion serving as a bottomed hole 14 for embedding a thermocouple (diameter: 1.1 mm, depth: 2 mm) )
Was formed.

(4) A conductor paste was printed by screen printing on the plate-like body subjected to the processing of (3) above. The printing pattern was a concentric pattern as shown in FIG. As the conductor paste, Solvest PS603D manufactured by Tokuri Chemical Laboratory, which is used for forming through holes in a printed wiring board, was used. This conductor paste is a silver-lead paste, and lead oxide (5% by weight), zinc oxide (55% by weight) and silica (10% by weight) are based on 100 parts by weight of silver.
% By weight), 7.5 parts by weight of a metal oxide composed of boron oxide (25% by weight) and alumina (5% by weight). The silver particles have an average particle size of 4.5 μm.
And it was scaly.

(5) Next, the heater plate 11 on which the conductor paste is printed is heated and fired at 780 ° C. to sinter silver and lead in the conductor paste and to bake the heater plate 11 to form the heating element 12. did. The silver-lead heating element had a thickness of 5 μm, a width of 2.4 mm, and a sheet resistivity of 7.7 mΩ / □.

(6) Nickel sulfate 80 g / l, sodium hypophosphite 24 g / l, sodium acetate 12 g / l,
The heater plate 11 prepared in the above (5) is immersed in an electroless nickel plating bath composed of an aqueous solution having a concentration of boric acid of 8 g / l and ammonium chloride of 6 g / l. A metal coating layer (nickel layer) 12a was deposited.

(7) Screen printing is applied to the portion where the external terminal 13 for securing the connection with the power supply is attached.
A solder layer was formed by printing silver-lead solder paste (manufactured by Tanaka Kikinzoku). Next, the external terminal 13 made of Kovar was placed on the solder layer, and heated and reflowed at 420 ° C. to attach the external terminal 13 to the surface of the heating element.

(8) A thermocouple for temperature control was sealed with polyimide to obtain a ceramic heater 10.

Example 3 Production of Electrostatic Chuck (See FIGS. 3 to 5) (1) 100 parts by weight of aluminum nitride powder (manufactured by Tokuyama Co., average particle size 1.1 μm), yttria (average particle size:
0.4 μm) 4 parts by weight, acrylic binder 11.5 parts by weight, dispersant 0.5 parts by weight, sucrose 0.2 parts by weight and 1
Using a paste obtained by mixing 53 parts by weight of alcohol composed of butanol and ethanol, molding was performed by a doctor blade method to obtain a green sheet having a thickness of 0.47 mm.

(2) Next, the green sheet is heated to 80 ° C.
After drying for 5 hours, the green sheet that needs to be processed is punched with a diameter of 1.8 mm, 3.0 mm,
A portion serving as a through hole for inserting a 5.0 mm semiconductor wafer support pin and a portion serving as a through hole for connecting to an external terminal were provided.

(3) 100 parts by weight of tungsten carbide particles having an average particle diameter of 1 μm, acrylic binder 3.0
By weight, 3.5 parts by weight of the α-terpineol solvent and 0.3 parts by weight of the dispersant were mixed to prepare a conductor paste A. A conductive paste B was prepared by mixing 100 parts by weight of tungsten particles having an average particle diameter of 3 μm, 1.9 parts by weight of an acrylic binder, 3.7 parts by weight of an α-terpineol solvent, and 0.2 parts by weight of a dispersant. This conductive paste A
Was printed on a green sheet by screen printing to form a conductor paste layer. The printing pattern was a concentric pattern. Further, a conductor paste layer composed of an electrostatic electrode pattern having the shape shown in FIG. 4 was formed on another green sheet.

Further, a conductive paste B was filled in a through hole for a through hole for connecting an external terminal. On the green sheet 500 on which the pattern of the resistance heating element is formed,
Further, 34 green sheets 500 ′ on which no tungsten paste is printed are laminated on the upper side (heating surface) and 13 green sheets are laminated on the lower side, and a green sheet 500 on which a conductive paste layer composed of an electrostatic electrode pattern is printed is laminated thereon. Further, two green sheets 500 'on which no tungsten paste is printed are further laminated thereon,
The laminate was formed by pressure bonding at a pressure of 0 kg / cm ² (FIG. 5A).

(4) Next, the obtained laminate was degreased in nitrogen gas at 600 ° C. for 5 hours, and at 1890 ° C. under a pressure of 150
It was hot-pressed at kg / cm ² for 3 hours to obtain an aluminum nitride plate having a thickness of 3 mm. This was cut out into a 230 mm disk shape, and a resistance heating element 50 having a thickness of 6 μm and a width of 10 mm and a chuck positive electrode electrostatic layer 2 having a thickness of 10 μm were formed therein.
0, a plate made of aluminum nitride having the chuck negative electrode electrostatic layer 30 (FIG. 5B).

(5) Next, the plate obtained in (4) is
After polishing with a diamond grindstone, a mask is placed and Si
A bottomed hole (diameter: 1.2 mm, depth: 2.0 mm) for a thermocouple was provided on the surface by blasting treatment with C or the like. At this time, the roughness of the ceramic surface was Rmax = 3 μm. In addition, the wafer mounting / holding surface is polished so that Rma
x = 1.5 μm.

(6) Further, the portions where the through holes are formed are cut out to form blind holes 130 and 140 (FIG. 5).
(C)) Using a brazing filler metal made of Ni-Au in the blind holes 130 and 140, the external terminals 60 and 180 made of Kovar were connected by heating and reflow at 700 ° C. (FIG. 5).
(D)). The connection of the external terminals is desirably a structure in which a tungsten support is supported at three points. This is because connection reliability can be ensured.

(7) Next, a plurality of thermocouples for temperature control were embedded in the bottomed holes, and the manufacture of the electrostatic chuck having the resistance heating element was completed. Finished electrostatic chuck (Fig. 3)
Is a heater (resistance heating element) in the ceramic substrate 100.
Pattern 50 and positive / negative chuck electrostatic layer (electrostatic electrode) 2
0 and 30 are buried. The positive and negative chuck electrostatic layers (electrostatic electrodes) 20 and 30 are, as shown in FIG.
0b and the comb electrode 30b face each other, and there are connection electrodes 20a and 30a for electrically connecting the comb electrodes. On the positive and negative chuck electrostatic layers (electrostatic electrodes) 20 and 30, a ceramic dielectric film 40 having a thickness of about 300 μm is formed. The ceramic dielectric film 40 can be set in the range of 50 to 2000 μm.

Embodiment 4 The same as Embodiment 3 except that the ceramic substrate 10
0 was treated by sandblasting, and the surface roughness of both surfaces was set to Rmax = 3 μm.

Comparative Example 1 In this comparative example, an aluminum nitride plate was obtained in the same manner as in (1) to (4) of Example 1, and the average particle diameter was 0.5 μm on the mounting surface of the wafer. Si
A sand blasting process for blowing C particles was performed, while a sand blasting process for blowing 5 μm SiC particles on the opposite side was performed. Thereafter, a ceramic heater was obtained in the same manner as in (5) to (7) of Example 1. The surface roughness of the wafer mounting / holding surface of the obtained ceramic heater is JIS B
0601 Rmax = 1 μm, and the surface roughness of the opposite side surface was Rmax = 4.8 μm.

(Comparative Example 2) In this comparative example, an aluminum nitride plate was obtained in the same manner as in (1) to (4) of Example 1, and SiC particles having an average particle diameter of 0.1 μm were coated on both surfaces. A sand blasting process is performed, and then, Example 1 is performed.
A ceramic heater was obtained in the same manner as (5) to (7). The surface roughness of the wafer mounting / holding surface of the obtained ceramic heater was JIS B 0601 Rmax = 0.08.
μm, and the surface roughness of the opposite side surface is Rmax = 0.07.
μm.

Comparative Example 3 In this comparative example, after obtaining an aluminum nitride plate in the same manner as in (1) to (4) of Example 1, SiC particles having an average particle diameter of 250 μm are sprayed on both surfaces. A sand blasting process was performed, and then Example 1
A ceramic heater was obtained in the same manner as (5) to (7). The surface roughness of the wafer mounting / holding surface of the obtained ceramic heater is JIS B 0601 Rmax = 260 μm
m, and the surface roughness of the opposite side is Rmax = 210 μm
Met. (Reference Example) The same as Comparative Example 1 except that the diameter was 150 mm.
(6 inches).

[0086]Evaluation method  Ceramics obtained in Examples 1-2 and Comparative Examples 1-3
After heating the heater to 600 ° C and returning it to normal temperature,
The amount was checked. The amount of warpage is measured by a Kyocera shape measuring instrument.
It was measured using a “nanoway”. The result is
The results are shown in Table 1.

[0087]

[Table 1]

As shown in Table 1, in the ceramic heaters according to Examples 1 and 2, Rmax was in the range of 0.1 to 250 μm, and the difference in surface roughness between both surfaces was 13% (Example 1). ) And 7% (Example 2), the warpage amount is also 3%.
μm (Examples 1 and 2) and Comparative Example 1
Ceramic heater according to the above, the difference in surface roughness of both surfaces is 79%
Therefore, the warpage amount is as large as 10 μm, and the ceramic heater according to Comparative Example 2 has a warpage due to stress because the surface roughness value of both surfaces is too small.
μm, and the ceramic heater according to Comparative Example 3 also has a warpage amount of 10 because the surface roughness value of both surfaces is too large.
It was as large as μm. Further, as seen from the reference example, if the diameter is less than 200 mm, the warp hardly occurs.

[0089]

As described above, according to the ceramic plate for a semiconductor manufacturing / inspection apparatus of the present invention, the surface roughness of both main surfaces of the ceramic substrate is adjusted to the above-mentioned predetermined range, and
50% difference in surface roughness between the wafer mounting / holding surface and the opposite side
Since the following adjustment is made, it is possible to prevent the ceramic substrate from being warped and the silicon wafer from being damaged due to the warpage.

[Brief description of the drawings]

FIG. 1 is a plan view schematically showing a ceramic heater which is an example of a ceramic plate for a semiconductor manufacturing / inspection apparatus of the present invention.

FIG. 2 is a cross-sectional view schematically showing a part of the ceramic heater shown in FIG.

FIG. 3 is a longitudinal sectional view schematically showing an electrostatic chuck which is an example of a ceramic plate for a semiconductor manufacturing / inspection apparatus of the present invention.

4 is a cross-sectional view of the electrostatic chuck shown in FIG. 3, taken along the line AA.

FIGS. 5A to 5D are cross-sectional views schematically showing a manufacturing process of the electrostatic chuck.

[Explanation of symbols]

 Reference Signs List 10 ceramic heater 11 heater plate 11a wafer mounting / holding surface 11b bottom surface 12 heating element 12a metal coating layer 13 external terminal 14 bottomed hole 15 through hole 16 support pin 19 silicon wafer 20 chuck positive electrode electrostatic layer 30 chuck negative electrode electrostatic layer 20a, 30a Connection electrode 20b, 30b Comb-tooth electrode 40 Ceramic dielectric film 50 Resistance heating element 100 Ceramic substrate 101 Electrostatic chuck

Claims (2)

[Claims] 1. A ceramic plate for a semiconductor manufacturing / inspection apparatus wherein a semiconductor wafer is mounted on a surface of a ceramic substrate or a semiconductor wafer is held at a predetermined distance from the surface of the ceramic substrate.
The surface roughness based on SR0601 is Rmax = 0.1
２５０250 μm, and the surface roughness of the wafer mounting / holding surface of the ceramic substrate and the surface roughness of the opposite side surface are the same, or the surface roughness of the wafer mounting / holding surface and the opposite. A ceramic plate for a semiconductor manufacturing / inspection device, wherein a difference from a side surface roughness is 50% or less. 2. The ceramic substrate has a disk shape,
2. The ceramic plate for a semiconductor manufacturing / inspection apparatus according to claim 1, wherein the diameter is 200 mm or more and the thickness is 50 mm or less.