JP2014207374A - Part for semiconductor manufacturing device, and method for manufacturing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a part for a semiconductor manufacturing device having a ceramic member and a metal member bonded together by an adhesive layer, and arranged so that the adhesive layer serves to relax stress and has good adhesion, and to provide a method for manufacturing such part for a semiconductor manufacturing device.SOLUTION: A part (1) for a semiconductor manufacturing device comprises: a ceramic member (9); a metal member (15); and a first adhesive layer (97) disposed between the ceramic member (9) and the metal member (15) for bonding together the ceramic member (9) and the metal member (15). The contact angles of water to the ceramic member (9) and the metal member (15) are 90° or less. The first adhesive layer (97) is 100% or more in elongation, and 70 or less in shore A hardness.

Description

  The present invention relates to a component for a semiconductor manufacturing apparatus and a method for manufacturing the same, and, for example, a component for a semiconductor manufacturing apparatus that can be applied to an electrostatic chuck used for fixing a semiconductor wafer, correcting the flatness of a semiconductor wafer, and the like. It is about.

  2. Description of the Related Art Conventionally, in a semiconductor manufacturing apparatus used for manufacturing a semiconductor wafer, a process such as dry etching (for example, plasma etching) is performed on a semiconductor wafer (for example, a silicon wafer). In order to increase the accuracy of this dry etching, it is necessary to securely fix the semiconductor wafer. Therefore, an electrostatic chuck for fixing the semiconductor wafer by electrostatic attraction has been proposed as a fixing means for fixing the semiconductor wafer. (For example, refer to Patent Document 1).

  Specifically, the electrostatic chuck described in Patent Document 1 has a suction electrode inside a ceramic insulating plate, and a semiconductor using an electrostatic attraction generated when a voltage is applied to the suction electrode. The wafer is adsorbed on the upper surface (adsorption surface) of the ceramic insulating plate.

  In this type of electrostatic chuck, a metal base that functions as a cooling plate is bonded to the lower surface (bonding surface) of a ceramic insulating plate via an adhesive layer (bonding layer) made of, for example, a resin material or a metal material. Is known.

  As an adhesive for the material of the adhesive layer, for example, an epoxy resin or a polyimide resin (see Patent Document 2) is known, and a technique for joining by metal bonding (see Patent Document 3) is also disclosed. .

JP 2008-205510 A JP 2010-129845 A Japanese Patent No. 2694668

However, when joining (adhering) using the above-mentioned conventional adhesive, there are the following problems.
The electrostatic chuck is often used in an environment where the temperature is changed, for example, when processing a semiconductor wafer, but the difference in thermal expansion coefficient between the ceramic insulating plate and the metal base is large. When a large thermal stress is applied to the electrostatic chuck, there is a problem that the adhesive layer peels off or the electrostatic chuck is deformed (for example, curved) depending on the case.

  Therefore, it is desirable that the adhesive layer disposed between the ceramic insulating plate and the metal base is made of an elastic material that can relieve stress, but epoxy resins and polyimide resins have high elastic modulus. Stress relaxation is not easy. Also, in the case of metal bonding, since the elastic modulus is high, stress relaxation is similarly difficult.

  The present invention has been made in view of the above problems, and its purpose is to bond a ceramic member and a metal member with an adhesive layer, such as an electrostatic chuck in which a ceramic insulating plate and a metal base are bonded. An object of the present invention is to provide a semiconductor manufacturing device component having an adhesive layer that can relieve stress and has good adhesion, and a method for manufacturing the same.

  (1) As a first aspect of the present invention (part for a semiconductor manufacturing apparatus), a ceramic member, a metal member, and the ceramic member and the metal member are disposed between the ceramic member and the metal member. In the semiconductor manufacturing apparatus component including the first adhesive layer, a contact angle of water with respect to the ceramic member and the metal member is 90 ° or less, and the first adhesive layer is elongated. The rate is 100% or more, and the hardness of Shore A is 70 or less.

  In the semiconductor manufacturing apparatus component of the first aspect, since the contact angle of water with respect to the ceramic member and the metal member is 90 ° or less, the adhesion of the first adhesive layer to the ceramic member and the metal member is high and high. Has bonding strength.

  Here, when the contact angle of water is small (in the case of 90 ° or less), it indicates that the ceramic member and the metal member have high affinity for a highly polar compound. This is because, for example, an adhesion-imparting agent (described later) or an adhesion assistant (described later) having a polar group contained in the first adhesive layer is likely to gather at the interface between the ceramic member and the metal member and the adhesive. This is because it contributes greatly. In addition, the present inventors have confirmed by an experiment described later that adhesion is improved when the contact angle of water is 90 ° or less.

Here, the contact angle of water will be described. As illustrated in FIG. 9, the contact angle θ of water, the surface tension γ _w of water, the water / substrate interface tension γ _WS and the surface tension γ _S of the substrate (base material). There is a relationship represented by the following formula (1) which is Young's formula.

γ _S = γ _WS + γ _W · cos θ (1)
Here, γ _S and γ _W are constant because they are unique values for each substance. The γ _WS is a stress acting between a solid (base material) and a liquid (adhesive). The smaller the γ _WS is, the more the wetting is promoted and the adhesive force is more easily expressed. In order to reduce this, it is understood that cos θ is large, that is, θ is small, that is, it is better that the contact angle is small.

  In the first aspect, since the first adhesive layer has an elongation of 100% or more and a Shore A hardness of 70 or less, the first adhesive layer is excellent in stretchability and flexibility. Therefore, even if the difference in the thermal expansion coefficient between the ceramic member and the metal member is large and the temperature change is repeated, the first adhesive layer is hardly peeled off (that is, interface peeling hardly occurs). There is an advantage that the semiconductor manufacturing apparatus component is not easily deformed by thermal stress.

In addition, the present inventors have confirmed by experiments described later that peeling can be suppressed and an excellent effect can be obtained when the elongation is 100% or more and the hardness of Shore A is 70 or less.
Here, the term “elongation rate” indicates the elongation performance of rubber, and the ratio of the elongation of rubber when stretched to the breaking limit ((length at break / length before stretch) × 100 [% ]). Shore A is a standard indicating the hardness of rubber and is defined in JIS K6253.

(2) The present invention, as a second aspect, is characterized in that the thermal conductivity of the first adhesive layer is 0.5 W / m · K or more and 2 W / m · K or less.
In the second aspect, the thermal conductivity of the first adhesive layer is as high as 0.5 W / m · K or more and 2 W / m · K or less. For example, the first adhesive layer is heated during processing of a semiconductor wafer. Even if it is done, it is easy to be cooled, and the heat burden on the first adhesive layer is small. Therefore, the effect that deterioration of an adhesive agent can be suppressed and it can be used for a long time is acquired.

  Here, if the thermal conductivity is too high, the temperature variation on the surface of the ceramic member becomes large, or the ceramic member is easily cooled and the efficiency when the ceramic insulating plate is heated by the heater is lowered. The thermal conductivity can be appropriately adjusted by adding various inorganic fillers.

(3) As a third aspect, the present invention is characterized in that the first adhesive layer contains an addition-type silicone resin, a platinum-based catalyst, an adhesion-imparting agent, and an inorganic filler.
The third aspect illustrates a preferable material for the first adhesive layer.

In addition, in order to promote hardening, a platinum-type catalyst is added in order to improve adhesiveness, an inorganic filler (inorganic powder) is added in order to improve adhesiveness, in order to express adhesive force.
(4) The present invention provides, as a fourth aspect, a second adhesive layer different from the first adhesive layer along an edge (for example, an outer peripheral portion) in the planar direction of the first adhesive layer. It is provided with.

In the fourth aspect, the first adhesive layer and the second adhesive layer (different from that) are arranged in the planar direction of the first adhesive layer (the direction in which the first adhesive layer spreads). ing.
Therefore, characteristics in the planar direction (for example, thermal characteristics and mechanical characteristics) of the component for semiconductor manufacturing apparatus can be arbitrarily set. Thus, there is an advantage that components having various characteristics can be obtained.

(5) As a fifth aspect, the present invention is characterized in that the thermal conductivity of the first adhesive layer is different from the thermal conductivity of the second adhesive layer.
In the fifth aspect, since the thermal conductivity of the first adhesive layer and the thermal conductivity of the second adhesive layer are different, the thermal characteristics in the planar direction of the semiconductor manufacturing apparatus component can be arbitrarily set. As a result, there is an advantage that the processing speed at a predetermined place can be arbitrarily adjusted when processing such as plasma etching is performed.

  (6) As a sixth aspect of the present invention, as the sixth aspect, in the semiconductor manufacturing apparatus component, the ceramic member is made of an electrically insulating material, the ceramic member has an adsorption electrode, and a voltage is applied to the adsorption electrode. It is an electrostatic chuck that attracts an object to be attracted by using an electrostatic attractive force generated when the material is attracted.

The sixth aspect shows a preferable example as a component for a semiconductor manufacturing apparatus.
(7) The present invention (a method for manufacturing a component for a semiconductor manufacturing apparatus) includes, as a seventh aspect, a first step of preparing a ceramic member and a metal member having a water contact angle of 90 ° or less, and the first step. As a varnish for forming the adhesive layer, a varnish having a viscosity at 10 s ⁻¹ of 60 to 200 Pa · s obtained by a rotational viscometer and a thixotropy index of 1 to 3 at a shear rate of 1 s ⁻¹ and 10 s ^−1. And applying the varnish to a region where the first adhesive layer is formed on the surface of the ceramic member or the metal member, and using the varnish, the ceramic member and the metal member And a third step of bonding.

In the seventh aspect, a ceramic member and a metal member having a water contact angle of 90 ° or less are used as the ceramic member and the metal member, and a varnish for forming the first adhesive layer is obtained by a rotational viscometer. A varnish having a viscosity at 10 s ⁻¹ of 60 to 200 Pa · s and a thixotropic index of 1 to 3 at a shear rate of 1 s ⁻¹ to 10 s ⁻¹ , that is, a varnish having a predetermined viscosity or thixotropy index is used. And a varnish is apply | coated to the area | region which forms the 1st adhesive bond layer of the surface of a ceramic member or a metal member, and a ceramic member and a metal member are adhere | attached using the varnish.

  By adhering the ceramic member and the metal member in this manner, there is an effect that the varnish (and hence the first adhesive layer on which the varnish is cured) is in close contact with the ceramic member and the metal member, and is firmly bonded.

  In addition, since the varnish viscosity and thixotropy index are moderate, there is an advantage that when the varnish is applied to a ceramic member or a metal member, the application work is easy and the varnish is difficult to flow out of the region. . In particular, since the thixotropy index is moderate, there is an advantage that the wettability between the ceramic member as the base material and the metal member is good and the adhesiveness is good, thereby improving the adhesiveness.

Here, the varnish is a substance that has fluidity and can be applied.
The thixotropy index indicates the ratio between the viscosity at a low shear rate and the viscosity at a high shear rate. Here, the ratio between the viscosity at a shear rate of 1 s ^{-1 and} the viscosity at a shear rate of 10 s ^-1 is indicated. ing.

  (8) In the present invention, as an eighth aspect, before the third step, a dam for preventing the varnish from flowing out is provided around a region where the first adhesive layer is formed, and is surrounded by the dam. The varnish is applied to the region.

  In the eighth aspect, a dam that prevents the varnish from flowing out is provided around the area where the first adhesive layer is formed, and then the varnish (for the first adhesive layer) is surrounded by the dam. Since varnish is applied, it is possible to prevent the varnish from flowing out of the predetermined area.

(9) As a ninth aspect of the present invention, the viscosity of the varnish forming the dam is greater than the viscosity of the varnish of the first adhesive layer.
In the ninth aspect, since the viscosity of the varnish forming the dam is larger than the viscosity of the varnish of the first adhesive layer, when the dam varnish is applied, the shape of the applied portion is easily maintained. can do. Therefore, the dam can be formed with high accuracy.

  Since a material having a low thixotropy index has high fluidity and easily flows out, it is preferable that the varnish forming the dam has a thixotropy index equal to or higher than that of the varnish for the first adhesive layer.

As a method for increasing the thixotropy index, for example, there is a method of adding nano-sized particles (inorganic filler) having a particle size of 20 nm or less.
Here, when a small-sized inorganic filler is added, the thixotropy index increases and it becomes difficult to flow. Therefore, the thickness of each adhesive layer can be controlled by adjusting the thixotropy index.

1 is a perspective view showing a part of an electrostatic chuck according to an embodiment. It is explanatory drawing which expands and shows the part which fractured | ruptured the electrostatic chuck of the Example in the thickness direction. It is explanatory drawing which shows the supply state of the electric power for fracture | rupturing the electrostatic chuck of an Example in the thickness direction, and driving an electrostatic chuck. It is explanatory drawing which fractures | ruptures the electrostatic chuck of an Example in the thickness direction, and shows the electrical connection part with respect to the one part electrode and heater of an electrostatic chuck. (A) The top view which shows the joining surface side of a ceramic insulating board, (b) The top view which shows the joining surface side of a metal base. It is explanatory drawing which shows arrangement | positioning of the dam and an adhesive bond layer in a metal base joint surface. It is explanatory drawing which shows typically the joining process in the manufacturing method of an electrostatic chuck. (A) Explanatory drawing which shows the pattern of the application part of the dam formation material in the joint surface of a metal base, (b) is explanatory drawing which shows the adhesive agent applied between dams. It is explanatory drawing explaining a contact angle.

Below, the form for implementing this invention is demonstrated.
[Embodiment]
-As a material of the ceramic member, alumina, aluminum nitride, and yttria are listed. Of these, alumina is excellent in terms of strength and wear resistance. Aluminum nitride is excellent in terms of thermal conductivity. Furthermore, yttria is excellent in plasma resistance.

  -As a material of a metal member, aluminum, titanium, or those alloys are mentioned. Among these, aluminum and its alloys are excellent in workability and cost. Titanium and its alloys have a small coefficient of thermal expansion and can suppress stress due to a difference in thermal expansion from ceramic.

  As the material for the first adhesive layer, a silicone resin (such as a thermosetting resin) is preferable in consideration of heat resistance. In order to increase the elongation percentage after curing of the adhesive composition, it is preferable to contain a silicone resin having an addition type functional group having a molecular weight of 30,000 or more. The silicone curing reaction includes a condensation type, a peroxide cross-linking type, and an addition type, but the addition type is preferred because there are no by-products. Examples of the catalyst include rhodium and platinum. Highly reactive platinum is preferable. Examples of the inorganic powder include silica, alumina, yttrium oxide, yttrium fluoride, aluminum nitride, silicon carbide, and silicon nitride.

  As examples of the silicone resin (addition type), for example, KE-1820, KE-1823, KE-1825, KE-1862, KE-1831, KE-1884, KE-1885 manufactured by Shin-Etsu Chemical, SE1700 manufactured by Toray Dow Corning SE1720CV, SE4402, SE1714, XE13-B3208, TSE322S, TSE3380, XE14-A0425, and TSE3331K manufactured by Momentive can be used.

  In addition, a well-known thermosetting addition type silicone adhesive can be used as the said silicone resin example (addition type). Specifically, the thermosetting addition type silicone adhesive contains, for example, a polyorganosiloxane containing an alkenyl group (alkenyl group-containing silicone) as a functional group in the molecule and a hydrosilyl group as a functional group in the molecule. The polyorganosiloxane is an essential constituent.

  The polyorganosiloxane having an alkenyl group as a functional group in the molecule is preferably a polyorganosiloxane having two or more alkenyl groups in the molecule. Examples of the alkenyl group include a vinyl group (ethenyl group), an allyl group (2-propenyl group), a butenyl group, a pentenyl group, and a hexenyl group. In particular, a vinyl group and a hexenyl group are preferable. The alkenyl group is usually bonded to a silicon atom (for example, a terminal silicon atom or a silicon atom inside the main chain) of the polyorganosiloxane forming the main chain or skeleton.

  Examples of the polyorganosiloxane forming the main chain or skeleton include polyalkylalkylsiloxanes (polydialkylsiloxanes) such as polydimethylsiloxane, polydiethylsiloxane, and polymethylethylsiloxane, and polyalkylarylsiloxanes. In addition, a copolymer [for example, poly (dimethylsiloxane-diethylsiloxane) or the like] in which a plurality of silicon atom-containing monomer components are used may be used. Of these, polydimethylsiloxane is preferred. That is, examples of the polyorganosiloxane having an alkenyl group as a functional group in the molecule include polydimethylsiloxane having a vinyl group as a functional group, polydimethylsiloxane having a hexenyl group as a functional group, and a mixture thereof.

  The polyorganosiloxane crosslinking agent containing a hydrosilyl group as a functional group in the molecule is a polyorgano having a hydrogen atom bonded to a silicon atom (particularly, a silicon atom having a Si-H bond) in the molecule. Polysiloxane having 2 or more silicon atoms having Si—H bond in the molecule is particularly preferable.

  The silicon atom having a Si-H bond may be either a silicon atom in the main chain or a silicon atom in the side chain, that is, may be contained as a constituent unit of the main chain, or It may be contained as a constituent unit of the side chain. Note that the number of silicon atoms in the Si—H bond is not particularly limited as long as it is two or more in one molecule.

  As the polyorganosiloxane crosslinking agent containing a hydrosilyl group as a functional group in the molecule, for example, polymethylhydrogensiloxane, poly (dimethylsiloxane-methylhydrogensiloxane) and the like are suitable.

  As examples of the silicone resin (condensation type), for example, KE-3490, KE-3498, KE-3490, KE-3494 manufactured by Shin-Etsu Chemical, SE9168, SE9185, SE9186, SE9188 manufactured by Toray Dow Corning may be used. it can. In the case of a condensation type silicone resin, a deacetone type is preferable from the viewpoint of heat resistance.

  -When adding an inorganic filler (for example, inorganic powder) to the material of the first adhesive layer, silica, alumina, aluminum, yttrium oxide, yttrium fluoride, aluminum nitride, silicon carbide, silicon nitride, Iron oxide, barium sulfate, and calcium carbonate can be used.

  In addition, when adding an adhesion imparting agent to the material of the first adhesive layer, as an adhesion imparting agent, a silane coupling agent (vinyltrimethoxysilane, vinyltriethoxysilane, vinyltrismethoxyethoxysilane, 2- (3,4-epoxycyclohexyl) ethyltrimethoxysilane, 3-glycidoxypropylmethyldimethoxysilane, 3-glycidoxypropyltrimethoxysilane, 3-glycidoxypropylmethyldiethoxysilane, 3-glycidoxypropyl Use of triethoxysilane, p-styryltrimethoxysilane, 3-methacryloxypropylmethyldimethoxysilane, 3-methacryloxypropyltrimethoxysilane, 3-acryloxypropyltrimethoxysilane, 3-isocyanatopropyltriethoxysilane, etc. it can.

  ・ Furthermore, when adding an adhesion aid to the material of the first adhesive layer, Shin-Etsu Chemical Primer AQ-1, Primer C, Primer A-10, Toray Dow Corning Primer D, Primer D-3, Momentive Toss Prime D, Toss Prime New F, etc. can be used.

  -As a material of the 2nd adhesive bond layer, the thing similar to the material of the 1st adhesive bond layer mentioned above is employable. Further, by configuring the first adhesive layer and the second adhesive layer from different materials, the first adhesive layer and the second adhesive layer have different characteristics (for example, thermal conductivity). Can be set to

  -The characteristics when applying the first and second adhesive layers (that is, the characteristics of the varnish) are specifically the viscosity and thixotropy index, for example, the amount of inorganic filler added and the size of the inorganic filler to be added (grain It can be set by adjusting the diameter). For example, the viscosity and thixotropy index can be increased by reducing the size of the inorganic filler. The viscosity and thixotropy index can also be adjusted by subjecting the inorganic filler to a surface treatment. As the surface treatment agent, the above-described silane coupling agent can be used. A commercially available material having the above-described characteristics can be selected and used.

  Examples for carrying out the present invention will be described below.

Here, for example, an electrostatic chuck capable of attracting and holding a semiconductor wafer is taken as an example of the semiconductor manufacturing apparatus component.
a) First, the structure of the electrostatic chuck of this embodiment will be described.

  As shown in FIG. 1, the electrostatic chuck 1 of this embodiment is a device that sucks the semiconductor wafer 3 on the upper side of FIG. 1, and includes a first main surface (suction surface) 5 and a second main surface (bonding surface). ) 7 (for example, diameter 300 mm × thickness 3 mm), disk-shaped ceramic insulating plate 9, first main surface (joint surface) 11 and second main surface (back surface) 13 (for example, diameter 340 mm × thickness 20 mm) ) A disk-shaped metal base (cooling plate) 15 is joined via a composite adhesive layer 17 made of a thermosetting adhesive.

Each configuration will be described below.
As will be described later, the ceramic insulating plate 9 is formed by laminating a plurality of ceramic layers, and is an alumina sintered body mainly composed of alumina. The water contact angle of the ceramic insulating plate 9 is 90 ° or less (for example, 90 °).

  Inside the ceramic insulating plate 9, there is provided a cooling gas supply path 19 that is a tunnel for supplying a cooling gas such as helium for cooling the semiconductor wafer 3, and the adsorption surface 5 has a cooling gas supply path 19. Are provided with a plurality of cooling openings 21 and annular cooling grooves 23 provided so that the cooling gas supplied from the cooling openings 21 spreads over the entire adsorption surface 5.

The cooling gas supply passage 19 has a gas through hole 20 that penetrates the electrostatic chuck 1 in the thickness direction and opens to the cooling opening 21.
On the other hand, the metal base 15 is made of, for example, aluminum or an aluminum alloy, and a cooling space 25 filled with a cooling liquid (for example, a fluorinated liquid or pure water) for cooling the ceramic insulating plate 9 is provided therein. It has been. The water contact angle of the metal base 15 is 90 ° or less (for example, 70 °).

  Furthermore, as shown in detail in FIG. 2, in the ceramic insulating plate 9, a plurality of layers (for example, six layers) first to sixth ceramic layers 27, 29, 31, 33, 35, and 37 are laminated. Here, although six ceramic layers 27 to 37 are shown, each ceramic layer 27 to 37 may be further composed of a plurality of ceramic layers.

  The configuration of the ceramic insulating plate 9 is basically the same as that of the prior art. Inside the ceramic insulating plate 9, a pair of suction electrodes 41, 43 having a semicircular planar shape, for example, are provided below the suction surface 5 (FIG. 2). (See FIG. 1) is formed.

  When the electrostatic chuck 1 is used, the attracting electrodes 41 and 43 apply a high DC voltage between the attracting electrodes 41 and 43, thereby attracting the semiconductor wafer 3 by an electrostatic attractive force ( (Suction force) is generated, and the semiconductor wafer 3 is suctioned and fixed by using this suction force.

Also, a heater (heating element) 45 that is spirally wound around the axis center in the same plane, for example, is formed below the attracting electrodes 41 and 43 (FIG. 2). .
As will be described in detail later, the ceramic insulating plate 9 and the metal base 15 are joined together by a double-structured composite adhesive layer 17 disposed between the joining surfaces 7 and 11.

b) Next, the electrical configuration of the electrostatic chuck 1 of the present embodiment will be described.
As shown in FIG. 3, a power circuit is connected to the suction electrodes 41 and 43 and the heater 45 of the electrostatic chuck 1 in order to operate them.

  Specifically, a first power supply circuit 51 is connected to the adsorption electrodes 41 and 43, and a second power supply circuit 53 is connected to the heater 45, and their operations are controlled by an electronic control unit 55 including a microcomputer. Is done.

  As shown in part in FIG. 4, the connection between the suction electrodes 41 and 43 and the heater 45 and the power supply circuits 51 and 55 is made by connecting terminals (terminal pins) 61, 63, 65 and 67 (FIG. 5 ( a))). FIG. 4 illustrates only a part of the connection terminals 61 to 67.

  That is, the adsorption electrodes 41 and 43 and the heater 45 are electrically connected to the metallized layers 79 and 81 of the internal holes 75 and 77 opened downward in the figure through the vias 69 and 71 and the internal conductive layer 73. Terminal metal fittings 83 and 85 are joined to the metallized layers 79 and 81, respectively, and connection terminals 61 to 67 are attached to the terminal metal fittings 83 and 85, respectively.

Therefore, power can be supplied to the adsorption electrodes 41 and 43 and the heater 45 via the connection terminals 61 to 67.
c) Next, the main part of the electrostatic chuck 1 of the present embodiment will be described.

  As shown in FIG. 5A, the bonding surface 7 of the ceramic insulating plate 9, the cooling gas supply passage 19 (specifically, the upper portion of the gas through-hole 20 is provided in the ceramic insulating plate 9 so as to penetrate in the thickness direction thereof. An upper through-hole 86) constituting the side is provided.

  Here, six gas through holes 20 are illustrated, but normally, in the gas through holes 20, lift pins (not shown) are used in order to separate the adsorbed semiconductor wafer 3 from the adsorption surface 5. ) Is inserted.

Further, the connection terminals 61 to 67 described above are erected on the joining surface 7 of the ceramic insulating plate 9 toward the front of the figure.
Similarly, as shown in FIG. 5B, the metal base 15 has a joining surface 11, and the cooling gas supply path 19 (specifically, the lower portion of the gas through-hole 20 is also penetrated to the metal base 15 in the thickness direction. A lower through-hole 87) constituting the side is provided.

The metal base 15 is provided with four terminal through holes 88 through which the connection terminals 61 to 67 are inserted so as to penetrate in the thickness direction.
In particular, in this embodiment, as shown in FIG. 6 on the side of the joining surface 11 of the metal base 15, a predetermined width (for example, 2 mm) is provided on the inner circumference along the outer circumference circle 89 on which the ceramic insulating plate 9 is superimposed. Thus, an annular external dam 91 having a predetermined thickness (for example, 250 μm) is formed.

  Further, an annular first internal dam 93 having a predetermined width (for example, 2 mm) and a predetermined thickness (for example, 250 μm) is formed so as to surround the opening 87 a of the lower through hole 87, and the opening of the terminal through hole 88 is further formed. An annular second internal dam 95 having a predetermined width (for example, 2 mm) and a predetermined thickness (for example, 250 μm) is formed so as to surround the portion 88a. In addition, the 2nd adhesive bond layer is comprised by each dam 91-95.

And each of these dams 91-95 is comprised by the silicone adhesive (For example, Shin-Etsu Chemical KE-1820 and its viscosity adjustment goods) which are thermosetting adhesives.
The thermal conductivity of each of the dams 91 to 95 is 0.5 W / m · K or more and 2 W / m · K or less (for example, 1.0 W / m · K). It's okay.

  Further, a region S surrounded by the external dam 91 and the first and second internal dams 93 and 95, that is, the inside of the external dam 91 (in the plane direction of the joint surface 11) and the first and second internal dams 93, In the closed region S between the outer side of 95, an adhesive layer (first adhesive layer) 97 made of a thermosetting adhesive that is, for example, a silicone adhesive, is configured in the same manner as each of the dams 91 to 95. Has been.

  That is, the composite adhesive layer 17 between the ceramic insulating plate 9 and the metal base 15 includes the external dam 91, the first and second internal dams 93 and 95, and the first adhesive layer 97. . That is, the composite adhesive layer 17 has a double structure of the dams 91 to 95 that are annular first adhesive layers and the first adhesive layer 97 in the region S therebetween.

  The first adhesive layer 97 has an elongation of 100% or more (for example, 200%) and a Shore A hardness of 70 or less (for example, 45). The thermal conductivity of the first adhesive layer 97 is, for example, not less than 0.5 W / m · K and not more than 2 W / m · K (for example, 1.0 W / m · K). Here, the thermal conductivity of the first adhesive layer 97 may be the same as the thermal conductivity of each of the dams 91 to 95, but may be different.

d) Next, a method for manufacturing the electrostatic chuck 1 of this embodiment will be described.
<Method for Manufacturing Ceramic Insulating Plate 9>
(1) Although not shown in the figure, as raw materials, Al ₂ O ₃ : 92% by weight, MgO: 1% by weight, CaO: 1% by weight, SiO ₂ : 6% by weight of the main ingredients are mixed, After wet grinding with a ball mill for 50 to 80 hours, dehydration drying is performed.

  (2) Next, methacrylic acid isobutyl ester: 3% by weight, butyl ester: 3% by weight, nitrocellulose: 1% by weight, dioctyl phthalate: 0.5% by weight were added to this powder, and trichlor was further added as a solvent. -Add ethylene and n-butanol and mix with a ball mill to form a fluid slurry.

  (3) Next, this slurry is defoamed under reduced pressure and then poured into a flat plate and gradually cooled to emit the solvent, and the first to sixth (corresponding to the first to sixth ceramic layers 27 to 37). An alumina green sheet is formed.

  Then, with respect to the first to sixth alumina green sheets, a space serving as a cooling gas flow path such as the cooling gas supply path 19, a space serving as a through hole, an internal hole 75, 77, and vias 69, 71, Open the through hole at the required location.

(4) Further, a tungsten powder is mixed into the raw material powder for the alumina green sheet, and is made into a slurry by the same method as described above to obtain a metallized ink.
(5) Then, in order to form the adsorption electrodes 41 and 43, the heater 45, and the internal conductive layer 73, using the metallized ink, on the alumina green sheet corresponding to the location where each electrode or heater is formed, Each pattern is printed by the screen printing method. In addition, in order to form the vias 69 and 71, the metalized ink is filled in the through holes.

(6) Next, the first to sixth alumina green sheets are aligned so as to form a cooling gas flow path and the like, and thermocompression-bonded to form a laminated sheet.
(7) Next, the thermocompression-bonded laminated sheet is cut into a predetermined disc shape (for example, an 8-inch size disc shape).

  (8) Next, the cut sheet is fired in a reducing atmosphere in the range of 1400 to 1600 ° C. (for example, 1590 ° C.) for 5 hours to produce an alumina sintered body (ceramic insulating plate 9).

(9) Next, metallized layers 79 and 81 are formed on the ceramic insulating plate 9, and terminal fittings 83 and 85 are joined onto the metallized layers 79 and 81.
(10) Next, the connection terminals 61 to 67 are fitted and connected to the terminal fittings 83 and 85 to complete the ceramic insulating plate 9 with the connection terminals 61 to 67.

<Method of joining ceramic insulating plate 9 and metal base 15>
(1) As schematically shown in FIG. 7 (a), openings 87a corresponding to the planar shape (dam pattern) of each dam (external dam 91, first and second internal dams 93, 95) described above, The paste-like thermosetting adhesive having a predetermined viscosity (that is, having a viscosity capable of maintaining its own shape after application) on the joining surface 11 of the metal base 15 using a screen mask having 88a. Screen-print (varnish).

  As this thermosetting adhesive, it can be used as various silicone adhesives for the second adhesive layer used in, for example, Experimental Examples 1 to 3 described later. In addition, since the varnish of this thermosetting adhesive has a predetermined viscosity and a thixotropy index, it can maintain its shape after application.

  As a result, a plurality of annular dam pattern application portions 91a, 93a, and 95a (see dark gray portions in FIG. 8A) are formed at the positions where the external dam 91 and the first and second internal dams 93 and 95 are formed. Is done. That is, the application portions 91a, 93a, and 95a are formed at the positions where the external dam 91 and the first and second internal dams 93 and 95 are formed.

  (2) Next, as shown in FIG. 7B, the coating portions 91a, 93a, and 95a are dried and cured at a predetermined temperature (eg, about 100 ° C. to 150 ° C., up to about 200 ° C.). Let Thereby, the external dam 91 and the first and second internal dams 93 and 95 (see FIG. 8B) are formed.

  (3) Next, as shown in FIG. 7C, a screen mask having an opening corresponding to the region S in the region S surrounded by the external dam 91 and the first and second internal dams 93 and 95. Is used to screen-print a paste-like thermosetting adhesive (varnish) similar to the material used to form the dams 91 to 95.

  As the thermosetting adhesive, for example, various silicone adhesives for the first adhesive layer used in Experimental Examples 1 to 3 described later can be used. In addition, since the varnish of this thermosetting adhesive has a predetermined viscosity and a thixotropy index, it is possible to eliminate mask marks by leveling while suppressing variation in thickness due to flow after application.

Specifically, as a varnish for forming the first adhesive layer 97, the viscosity at 10 s ⁻¹ obtained with a rotational viscometer is 60 to 200 Pa · s, and the shear rate is 1 s ⁻¹ and 10 s ^−1. A varnish having a thixotropy index of 1 to 3 is used.

  Here, the viscosity and thixotropy index of the varnish of the thermosetting adhesive for the second adhesive layer are larger than the viscosity and the thixotropy index of the varnish of the thermosetting adhesive for the first adhesive layer. However, the same may be used.

As a result, the region application portion Sa (see the thin gray portion in FIG. 8B) is formed in the region S.
(4) Next, as shown in FIG. 7 (d), the ceramic insulating plate 9 is pressed from the joining surface 11 side of the metal base 15 (upper side in the figure).

  Specifically, the connection terminals 61 to 67 extending downward from the joint surface 7 side (lower side in the figure) of the ceramic insulating plate 9 are fitted into the terminal through holes 88 of the metal base 15, so that the ceramic insulating plate 9. Is moved downward.

(5) Next, as shown in FIG. 7 (e), the thermosetting adhesive is pressed from above on the joint surface 7 of the ceramic insulating plate 9.
Specifically, a load is applied by, for example, placing a weight on the ceramic insulating plate 9 and the ceramic insulating plate 9 is heated to a predetermined temperature (for example, about 140 ° C., up to about 200 ° C. at most) in an air atmosphere, and thermosetting adhesion is performed. The agent is dried and cured to form the first adhesive layer 97.

Thereby, the ceramic insulating plate 9 and the metal base 15 are joined by the thermosetting adhesive, and the electrostatic chuck 1 is completed.
e) Next, the effect of the present embodiment will be described.

  In the electrostatic chuck 1 of this embodiment, the contact angle of water with respect to the ceramic insulating plate 9 and the metal base 15 is 90 ° or less, so the first adhesive layer 97 with respect to the ceramic insulating plate 9 and the metal base 15 is used. Has high adhesion and high bonding strength.

  In the present embodiment, the first adhesive layer 97 has an elongation rate of 100% or more and a Shore A hardness of 70 or less, and thus has excellent stretchability and flexibility. Therefore, even if the ceramic insulating plate 9 and the metal base 15 have a large difference in thermal expansion coefficient and are used in a situation where the temperature change is repeated, the first adhesive layer 97 is difficult to peel off (that is, interface peeling hardly occurs). In addition, there is an advantage that the electrostatic chuck 1 is hardly deformed by thermal stress.

  Furthermore, in this embodiment, the thermal conductivity of the first adhesive layer 97 is 0.5 W / m · K or more and 2 W / m · K or less, so that the heat conductivity is high. Even when heated at this time, it is easy to cool, and the heat load on the first adhesive layer 97 is small. Therefore, the effect that deterioration of an adhesive agent can be suppressed and it can be used for a long time is acquired.

  In addition, in this embodiment, as a material for each of the dams 91 to 95 and the first adhesive layer 97, for example, a thermosetting adhesive made of a silicone resin is used, so that there is an advantage of excellent heat resistance. .

· In addition, in this embodiment, as a varnish for forming the first adhesive layer 97, a viscosity at 10s ^-1 obtained by rotating viscometer at 60～200Pa · s, shear rate 1s ^-1 and 10s ^-1 Since a varnish having a thixotropy index of 1 to 3 as a viscosity ratio is used, the coating operation is easy and the adhesiveness is excellent.

  Furthermore, in this embodiment, the dams 91 to 95 for preventing the varnish from flowing out are provided around the region S where the first adhesive layer 97 is formed, and then the regions surrounded by the dams 91 to 95. Since the varnish (for the first adhesive layer) is applied to S, the varnish can be prevented from flowing out of the predetermined region S.

In addition, since the viscosity and thixotropy index of the varnish forming each dam 91 to 95 is larger than the viscosity and thixotropy index of the first adhesive layer 97, the varnish of each dam 91 to 95 is applied In addition, the shape of the coated portion can be easily maintained. Therefore, each dam 91-95 can be formed accurately.
[Relationship between Claims and Examples]
The ceramic insulating plate 9 is a ceramic member, the metal base 15 is a metal member, the external dam 91, the first and second internal dams 93, 95 are the second adhesive layer, and the first adhesive layer 97 is the first. This corresponds to the adhesive layer.
<Experimental example>
Next, experimental examples conducted for confirming the effects of the present invention will be described.
(Experimental example 1)
In Experimental Example 1, as will be described later, an electrostatic chuck and a sample used for the experiment are manufactured by using the various materials by the method shown in the above-described Examples, and the first adhesive layer is peeled off. This is an investigation of the bonding state of Since the contents not described below are the same as those in the [Example], the description thereof is omitted.

In the following experiments, the contact angle was measured using DM-501 manufactured by Kyowa Interface Chemical Co., Ltd.
In addition, the addition type silicone adhesive contains an adhesion-imparting agent having a polar group, and the polar group is bonded to the base material to obtain adhesiveness. Therefore, the wettability of the base material surface and the adhesive is evaluated. Uses polar solvent water.

  The contact angle of the ceramic insulating plate made of alumina was changed by the following hydrophobic treatment and hydrophilic treatment. In the hydrophobic treatment, the substrate was immersed in a 4% octadecyltrimethoxysilane toluene solution at 75 ° C. for 30 minutes. In the hydrophilic treatment, it was immersed overnight in an ethanol solution of potassium hydroxide 0.2 mol / l. The contact angle with water increases by hydrophobic treatment, decreases by hydrophilic treatment, and the effect of each treatment increases by soaking for a long time.

  The viscosity was measured using a cone plate viscometer TVE-22H manufactured by Toki Sangyo Co., Ltd. The elongation was measured using an autograph (AG-IS) manufactured by Shimadzu Corporation. The hardness was measured using a rubber hardness tester GS-706 manufactured by Teclock Co., Ltd. The thermal conductivity was measured using QTM-500 manufactured by Kyoto Electronics Industry Co., Ltd.

In addition, in the samples (samples ^{1 to 4} , 10, and 11) described as having presence or absence of dams in Table 1, addition type silicone having a viscosity at 10 s ⁻¹ of a rotational viscometer of 70 Pa · s and a thixotropy index of 3.0. The adhesive was printed on the outer peripheral edge of the joint surface of the aluminum metal base having a contact angle of 70 ° and φ300 mm and the periphery of the opening to produce each dam (spacer part) having a thickness of 250 μm.

[Sample 1]
An addition-type silicone adhesive having a cured product elongation of 200% and a Shore A hardness of 45 is printed in the region S (the first adhesive layer forming region S) surrounded by each dam on the metal-based joint surface. Then, a ceramic insulating plate made of alumina having a contact angle of 70 ° was placed thereon, and was thermoset at 140 ° C., thereby producing an electrostatic chuck.

[Sample 2]
An addition-type silicone adhesive having a cured product elongation of 200% and a Shore A hardness of 45 is printed on a region S surrounded by each dam on the metal-based joining surface, and alumina having a contact angle of 80 ° is printed thereon. An electrostatic chuck was produced by installing a ceramic insulating plate made of the material and thermosetting at 140 ° C.

[Sample 3]
An addition-type silicone adhesive having a cured product elongation of 200% and a Shore A hardness of 45 is printed on a region S surrounded by each dam on the metal-based joining surface, and alumina having a contact angle of 90 ° is printed thereon. An electrostatic chuck was produced by installing a ceramic insulating plate made of the material and thermosetting at 140 ° C.

[Sample 4]
An addition-type silicone adhesive having a 100% cured product elongation and a Shore A hardness of 70 is printed on the region S surrounded by each dam on the metal-based joint surface, and alumina having a contact angle of 90 ° is printed thereon. An electrostatic chuck was produced by installing a ceramic insulating plate made of the material and thermosetting at 140 ° C.

[Sample 5]
A condensation-type (moisture-curing type) silicone adhesive having a 100% elongation of the cured product and a Shore A hardness of 60 was printed on the entire surface of an aluminum metal base having a contact angle of 70 ° and φ300 mm.

Further, an alumina ceramic insulating plate having a contact angle of 90 ° was placed thereon, followed by curing at 50 ° C. in a humidified atmosphere for 48 hours to produce an electrostatic chuck.
In this sample 5, no dam is formed.

[Sample 6]
Samples 6 and 7 were subjected to a simple adhesion test described later without performing an electrostatic chuck adhesion test. Using a ceramic insulating plate made of alumina having a contact angle of 120 ° and an aluminum plate having a contact angle of 70 °, the sample is bonded using the adhesive for the first adhesive layer having the same characteristics as the sample 1 to prepare a sample. did.

[Sample 7]
Using a ceramic insulating plate made of alumina with a contact angle of 100 ° and an aluminum plate with a contact angle of 70 °, the sample is bonded using the adhesive for the first adhesive layer having the same characteristics as the sample 1 to prepare a sample. did.

[Sample 8]
An addition-type silicone curable adhesive having a cured product elongation of 50% and a Shore A hardness of 75 was printed on the entire surface of an aluminum metal base having a contact angle of 70 ° and φ300 mm.

Further, an alumina ceramic insulating plate having a contact angle of 90 ° was placed thereon, followed by thermosetting at 120 ° C. to produce an electrostatic chuck.
In this sample 8, no dam is formed.

[Sample 9]
An addition type silicone curable adhesive having a cured product elongation of 30% and a Shore A hardness of 85 was printed on the entire surface of an aluminum metal base having a contact angle of 70 ° and φ300 mm.

Further, an alumina ceramic insulating plate having a contact angle of 90 ° was placed thereon, followed by thermosetting at 120 ° C. to produce an electrostatic chuck.
In this sample 9, no dam is formed.

[Sample 10]
An addition-type silicone adhesive having a cured product elongation of 110% and a Shore A hardness of 77 is printed on a region S surrounded by each dam on the metal-based joint surface, and alumina having a contact angle of 90 ° is printed thereon. An electrostatic chuck was prepared by installing a ceramic insulating plate made of heat and curing at 120 ° C.

[Sample 11]
A moldable silicone adhesive having a cured product elongation of 90% and a Shore A hardness of 45 is printed on the region S surrounded by each dam on the metal-based joint surface, and alumina having a contact angle of 90 ° is printed thereon. An electrostatic chuck was prepared by installing a ceramic insulating plate made of heat and curing at 120 ° C.

(Experiment contents)
And the experiment of the following content was conducted using each sample (samples 1-11) mentioned above.
Samples 1 to 5 are examples of the present invention.

a) Simple adhesion test In this simple adhesion test, a ceramic insulating plate (with dimensions of 12.5 mm in length x 25 in width x 0.3 mm in thickness) prepared to have each contact angle shown in Table 1 and a contact angle of 70 An aluminum plate (°: 12.5 mm long × 25 mm wide × 0.3 mm thick) with an area of 12.5 mm × 25 mm and a predetermined first adhesive layer adhesive for each sample. And bonded to prepare a sample of the bonded body. Then, the aluminum plate was peeled off from this sample. The results are shown in Table 1 below.

b-1) Electrostatic chuck adhesion test (peeling test after adhesion)
With respect to the electrostatic chucks of Samples 1 to 5 and Samples 8 to 11, the presence or absence of peeling of the electrostatic chuck (peeling in the first adhesive layer) was examined with ultrasonic waves. The results are also shown in Table 1 below.

b-2) Electrostatic chuck adhesion test (peeling test after durability)
The durability test which repeats raising / lowering temperature between 0 degreeC-150 degreeC was done with respect to the electrostatic chuck | zipper of the said samples 1-3. Thereafter, the presence or absence of peeling of the electrostatic chuck (peeling in the first adhesive layer) was examined with ultrasonic waves. Similarly, a peel test after durability was performed on the sample 11. The results are also shown in Table 1 below.

As is apparent from Table 1, in the simple adhesion test, in Samples 1 to 5 having a contact angle of 70 to 90 °, the adhesive itself is not broken, not the interface peeling (peeling on the surface of the first adhesive layer). Then, cohesive peeling that peels off occurred. This indicates that the adhesive strength at the interface is higher than the strength of the adhesive itself, and a sufficient adhesive strength is obtained. In the samples 6 and 7 having large contact angles of 120 ° and 100 °, interfacial peeling occurred. This indicates that the adhesive strength at the interface is lower than the strength of the adhesive itself, and sufficient adhesive strength is not obtained. That is, Samples 1 to 5 are preferable because they have higher adhesiveness than Samples 6 and 7.

Moreover, in the peeling test after adhesion, peeling was not seen in samples 1 to 5, but peeling was seen in samples 8 to 10.
In Samples 8 and 9, since the elongation was small and the hardness was high, the stress was not sufficiently relaxed, and the outer peripheral portion was peeled off. Moreover, although the sample 10 had large elongation, since the hardness was high, stress relaxation was insufficient and peeling was seen in the outer peripheral part.

  Furthermore, in the peeling test after durability, peeling was not seen in samples 1 to 3, but peeling was seen in sample 5. This is because when the adhesive is of the condensation type (moisture curing type), it is difficult to supply moisture to the center of the electrostatic chuck, the internal curing is insufficient, or there is outgassing during the reaction. It is thought that there is. Therefore, the addition type is considered to be more preferable.

In addition, since the sample 11 has a slightly small elongation, the initial adhesion is possible. However, in the peeling test after the endurance, the stress cannot be relaxed, and it is considered that the peeling occurred.
From Experimental Example 1, it was revealed that an adhesive having a contact angle of 90 ° or less, an elongation of 100% or more, and a Shore A hardness of 70 or less is preferable.
(Experimental example 2)
Here, the following samples 12 to 17 were used to examine the adhesive (for the first adhesive layer) and the state after application. Since the contents not described below are the same as those in the [Example], the description thereof is omitted.

In the following samples 12 to 17, as the adhesive for the first adhesive layer, the following predetermined amounts of the silica filler (average particle diameter of 0.6 μm) are added to the same resin composition as the sample 1 to conduct heat. Addition type silicone adhesives with different rates were prepared. And the following evaluation was performed using each addition type silicone adhesive. The results are shown in Table 2 below.
[Sample 12]
The addition type silicone adhesive which added 15 vol% of the said silica filler and was made into the heat conductivity 0.5W / m * K was used.

[Sample 13]
An addition-type silicone adhesive having 30 vol% of silica filler and a thermal conductivity of 1.0 W / m · K was used.

[Sample 14]
The addition type silicone adhesive which added 45 vol% of said silica fillers and made thermal conductivity 1.5W / m * K was used.

[Sample 15]
The addition type silicone adhesive which added 60 vol% of the said silica filler and was made into thermal conductivity 2.0W / m * K was used.

[Sample 16]
An addition-type silicone adhesive having a thermal conductivity of 0.3 W / m · K was used without adding the silica filler.

[Sample 17]
The addition type silicone adhesive which added 75 vol% of the said silica filler and was made into heat conductivity 2.5W / m * K was used.

(Experiment contents)
And the following content was evaluated using each sample (samples 12-17) mentioned above.

  The evaluation of the thermal efficiency of the heater was carried out by measuring the power consumption when a current was applied to the heater so that the ceramic insulating plate would be 120 ° C. A case where the temperature reaches 120 ° C. at a predetermined power consumption of 5000 W or less is indicated by ◯, and a case where the power consumption is not reached is indicated by ×. The durability of the adhesive was evaluated based on whether or not peeling occurred when heated and kept at 120 ° C. The case where peeling did not occur is shown as good, and the case where it occurred is shown as bad.

As shown in Table 2, when the thermal conductivity was 0.5 to 2.0 W · mK as in Samples 12 to 15, the two evaluations were good. The comprehensive evaluation means that both evaluations are good.

(Experimental example 3)
Here, the following samples 18 to 23 were used to examine the adhesive (for the first adhesive layer) and the state after the application.

Specifically, as the following samples 18 to 23, as the adhesive for the first adhesive layer, a predetermined amount of the alumina filler (alumina particles having an average particle diameter of 20 nm) is added to the same resin composition as the sample 1. By adding, an addition-type silicone adhesive in which the viscosity at 10 s ⁻¹ of the rotational viscometer and the thixotropy index were changed was produced.

And each addition type silicone adhesive was apply | coated on each metal base, respectively, the application state was evaluated from two points, flatness and leveling property, and the result was described in following Table 3.
Since the contents not described below are the same as those in Experimental Example 1, description thereof is omitted.

[Sample 18]
By adding 5 wt% of the alumina filler, an addition type silicone adhesive having a viscosity at 10 s ⁻¹ of a rotational viscometer of 70 Pa · s and a thixotropy index of 2.0 was used.
[Sample 19]
The alumina filler by adding 9 wt%, viscosity 180 Pa · s at 10s ^-1 of rotational viscometer, was used addition type silicone adhesive in which the thixotropy index of 3.0.
[Sample 20]
An addition type silicone adhesive having a viscosity of 10 Pa · s at 10 s ⁻¹ of the rotational viscometer and a thixotropy index of 1.0 was used without adding the alumina filler.
[Sample 21]
By adding 4 wt% of the alumina filler, an addition type silicone adhesive having a viscosity at 50 s · s of 10 s ⁻¹ of the rotational viscometer and a thixotropy index of 1.0 was used.

[Sample 22]
By adding 10 wt% of the alumina filler, an addition silicone adhesive having a viscosity at 210 s ⁻¹ of a rotational viscometer of 210 Pa · s and a thixotropy index of 3.0 was used.

[Sample 23]
By adding 15 wt% of the alumina filler, an addition-type silicone adhesive having a viscosity at 10 s ⁻¹ of 610 Pa · s and a thixotropy index of 5.0 was used.

  In Table 3, the flatness indicates that the flow in the manufacturing process is small and the in-plane thickness variation is good within the allowable range, and the flatness indicates that the flow in the manufacturing process is low. It shows that the in-plane thickness variation was outside the allowable range. Further, the leveling property is different from the flatness and represents the degree to which the unevenness on the surface is relaxed with the passage of time and the unevenness is eliminated. A leveling property of ◯ indicates that the mask marks on the surface of the adhesive layer disappeared and the good surface was obtained due to the relief of the unevenness. The leveling property of “x” indicates a case where the unevenness is not relaxed and a mask mark remains on the surface, and a good flat surface cannot be obtained.

As apparent from Table 3, the sample 23 had high viscosity and thixotropy index, so that the flatness and leveling properties were poor, mask marks remained after printing, and the thickness varied.

Further, it can be seen that the samples 20, 21, and 22 have poor flatness because the viscosity is out of an appropriate range.
On the other hand, Samples 18 and 19 had a viscosity of 60 to 200 Pa · s and a thixotropy index of 1 to 3, both of which were appropriate, and thus flatness and leveling properties were good.

In addition, this invention is not limited to the said embodiment and Example at all, and it cannot be overemphasized that it can implement with a various aspect in the range which does not deviate from this invention.
(1) For example, in the said Example, although silicone resin was mentioned as an example as an adhesive agent which comprises a dam (2nd adhesive bond layer), it is not restricted to silicone resin, Various heat | fever which can form a dam by application | coating An adhesive such as a curable adhesive can be used. The material is not limited to the thermosetting resin, and any material that can form a dam by coating may be used. For example, an adhesive such as a photocurable adhesive can be used.

  Similarly, in the said Example, although silicone resin was mentioned as an example as an adhesive agent which comprises a 1st adhesive bond layer, not only silicone resin but adhesives, such as various thermosetting adhesives, can be used. .

  (2) As an adhesive constituting the dam and the adhesive layer, the same kind of adhesive having the same thermal characteristics (for example, thermal conductivity) and mechanical characteristics (for example, Young's modulus) can be used. Different types of adhesives having different properties may be used.

Specifically, for example, KE-1867 manufactured by Shin-Etsu Chemical may be used as the material of the dam, and KE-1820 manufactured by Shin-Etsu Chemical may be used as the material of the first adhesive layer.
Further, different materials (adhesives) may be used so that the thermal conductivity of the dam and the thermal conductivity of the adhesive layer are different. That is, by making the thermal conductivity of the dam and the first adhesive layer different, the thermal characteristics on the adsorption surface can be arbitrarily changed.

  (3) In the above embodiment, the dam and the first adhesive layer are provided on the metal base side, but the adhesive may be provided on the ceramic insulating plate side, or provided on both the metal base and the ceramic insulating plate side. It's okay.

(4) In the above embodiment, the electrostatic chuck is cited as the semiconductor manufacturing apparatus component. However, the present invention can be applied to a CVD heater, a PVD heater, a shower head, and the like.
(5) Further, as a method for preventing the first adhesive layer varnish from flowing out, there is a method of arranging a spacer such as an O-ring around the outer peripheral edge or the opening of the joint surface. At this time, if the O-ring is a fluorine-based rubber, it is preferable because it has high stress resistance and etching resistance.

DESCRIPTION OF SYMBOLS 1 ... Electrostatic chuck 3 ... Semiconductor wafer 5 ... Adsorption surface 7, 11 ... Bonding surface 9 ... Ceramic insulating plate 15 ... Metal base 17 ... Composite adhesive layer 87a, 88a ... Openings 91, 93, 95 ... Dam (2nd Adhesive layer)
91a, 93a, 95a ... coating portion 97 ... first adhesive layer

Claims (9)

In a semiconductor manufacturing apparatus component comprising: a ceramic member; a metal member; and a first adhesive layer that is disposed between the ceramic member and the metal member and joins the ceramic member and the metal member.
The contact angle of water with respect to the ceramic member and the metal member is 90 ° or less,
The first adhesive layer has a stretch rate of 100% or more and a Shore A hardness of 70 or less.   2. The component for a semiconductor manufacturing apparatus according to claim 1, wherein the thermal conductivity of the first adhesive layer is 0.5 W / m · K or more and 2 W / m · K or less.   The semiconductor manufacturing apparatus component according to claim 1, wherein the first adhesive layer contains an addition-type silicone resin, a platinum-based catalyst, an adhesion-imparting agent, and an inorganic powder.   The second adhesive layer different from the first adhesive layer is provided along an edge portion in the planar direction of the first adhesive layer. Item for a semiconductor manufacturing apparatus according to the item.   The component for a semiconductor manufacturing apparatus according to claim 4, wherein the thermal conductivity of the first adhesive layer is different from the thermal conductivity of the second adhesive layer.   In the semiconductor manufacturing apparatus component, the ceramic member is made of an electrically insulating material, and the ceramic member has an adsorption electrode. The ceramic member is covered by electrostatic attraction generated when a voltage is applied to the adsorption electrode. The component for a semiconductor manufacturing apparatus according to claim 1, wherein the component is an electrostatic chuck for adsorbing an adsorbate. A method for manufacturing a component for a semiconductor manufacturing apparatus according to any one of claims 1 to 6,
A first step of preparing a ceramic member and a metal member having a water contact angle of 90 ° or less;
As the varnish forming the first adhesive layer, the viscosity at 10 s ⁻¹ obtained with a rotational viscometer is 60 to 200 Pa · s, and the thixotropy index, which is the viscosity ratio at shear rates of 1 s ⁻¹ and 10 s ⁻¹ , is 1. A second step of preparing ~ 3 varnish;
A third step of applying the varnish to a region where the first adhesive layer is formed on the surface of the ceramic member or the metal member, and bonding the ceramic member and the metal member using the varnish;
A method for manufacturing a component for a semiconductor manufacturing apparatus, comprising: Before the third step,
8. A dam for preventing the varnish from flowing out is provided around a region where the first adhesive layer is formed, and the varnish is applied to a region surrounded by the dam. Of manufacturing parts for semiconductor manufacturing equipment.   The method for manufacturing a component for a semiconductor manufacturing apparatus according to claim 8, wherein the viscosity of the varnish forming the dam is larger than the viscosity of the varnish of the first adhesive layer.