KR20170064469A - Electrostatic chuck - Google Patents

Abstract

[PROBLEM TO BE SOLVED BY THE INVENTION] It is possible to suppress the temperature of the ceramic span from becoming uneven due to the high temperature of the ceramics part close to the cavity.
The heater includes a plurality of overlapping heater portions which are a portion overlapping a center line of the ceramic span and a virtual straight line passing through the cavity, A first heater layer including a first redundant heater portion closest to the cavity when viewed in a first direction of the plurality of redundant heater portions; A second heater layer which is electrically connected to at least a part of the first heater layer and which is different from the first heater layer in a distance from the one surface and which is parallel to the imaginary straight line when viewed in the first direction among the plurality of overlapping heater sections And a second heater layer located on the same side of the first redundant heater portion with respect to the cavity in one second direction and including a second redundant heater portion next to the cavity next to the first redundant heater portion.

Description

{ELECTROSTATIC CHUCK}

The techniques disclosed herein relate to electrostatic chucking.

For example, in a semiconductor manufacturing apparatus, an electrostatic chuck for sucking and fixing a wafer by an electrostatic attractive force is used. As one type of electrostatic chuck, there is known an electrostatic chuck having a plate-shaped ceramic span formed by ceramics and a base plate arranged on one surface side of the ceramic span in the first direction. The wafer is placed on the surface of the ceramic span opposite to the one surface in the first direction (hereinafter referred to as "adsorption surface").

The ceramic span is provided with a heater composed of a resistance heating element, and the ceramic plate is heated by the heater, and the wafer placed on the adsorption face of the ceramic span is warmed. In order to suppress the temperature of the adsorption face of the ceramic span from being uneven in the face direction, the heater is arranged in a line between the center and the periphery of the ceramic span when viewed in the first direction And includes a plurality of heater portions.

A coolant flow path is formed in the base plate, and the coolant flows to the coolant flow path, thereby cooling the base plate and cooling the ceramic plate arranged to be able to transfer heat to the base plate. The base plate is provided with a cavity at a position different from the refrigerant flow path when viewed in the first direction. The cavity may include, for example, a fin-through hole into which a lift pin for separating the wafer placed on the ceramic span from the ceramic span is inserted, an inert gas for cooling the wafer by flowing between the wafer and the ceramic span Gas).

Patent Document 1: Japanese Utility Model Registration No. 3182120

Since the refrigerant flow path is not formed in the cavity of the base plate, the cooling effect by the refrigerant is low in the portion near the cavity of the ceramic span. Therefore, if a heater portion is disposed in a portion near the cavity in the ceramic span, a portion close to the cavity becomes high in temperature, and the temperature of the adsorption surface of the ceramic span is likely to become uneven in the surface direction have.

This specification discloses a technique capable of solving the above-described problems.

The techniques disclosed in this specification can be realized as the following embodiments.

(1) The electrostatic chuck disclosed in this specification includes a plate-shaped ceramic span provided with a heater composed of a resistance heating body and formed by ceramics, a ceramic span disposed on one surface side of the ceramic span in the first direction, And a base plate on which a refrigerant flow path is formed, wherein the base plate is provided with a cavity at a position different from the refrigerant flow path when viewed in the first direction, A plurality of overlapping heater portions which are a portion overlapping a center line of the ceramic span and a virtual straight line passing through the cavity, wherein a portion of the plurality of overlapping heater portions, which is closest to the cavity when viewed in the first direction, A first heater layer electrically connected to at least a part of the first heater layer and a distance from the one surface Is a second heater layer which is different from the first heater layer, wherein the first heater layer has a first overlapping portion in the second direction parallel to the virtual straight line when viewed in the first direction among the plurality of overlapping heater portions, And a second heater layer located on the same side as the heater portion and including a second redundant heater portion next to the first redundant heater portion.

According to the present electrostatic chuck, the heater includes a first heater layer including a plurality of overlapping heater portions which overlap a center line of the ceramic span and a virtual straight line passing through the cavity, and also includes a first overlapping heater portion closest to the cavity, And a second heater layer located on the same side as the first redundant heater portion for the cavity and including a second redundant heater portion next to the cavity next to the first redundant heater portion. The first heater layer and the second heater layer have different distances from one surface. As a result, the distance between the first redundant heater portion and the second redundant heater portion becomes longer as compared with the case where the first heater layer and the second heater layer are formed at the same distance from one surface, It is possible to suppress the temperature of the ceramic span from becoming uneven due to the high temperature of the portion.

(2) In the electrostatic chuck, the first heater layer may be separated from the other surface of the ceramic span opposite to the one surface of the second heater layer.

According to the present electrostatic chuck, since the portion near the cavity in the ceramic span is suppressed from becoming high temperature as compared with the case where the first heater layer is closer to one surface of the ceramic span than the second heater layer, Can be suppressed more effectively.

(3) In the electrostatic chuck, the second heater layer is an arc heater portion extending in an arc shape along the direction around the center of the ceramic span when viewed in the first direction, Further comprising an arcuate heater portion having a pair of heater ends disposed across the cavity in a direction in which the first overlapping heater portion is located, And may be configured to extend from one side of the pair of heater ends to the other side and electrically connected to the pair of heater ends.

According to the present electrostatic chuck, the arc heater portion adjacent to the first heater layer in the direction around the center of the ceramic insulator may be included in the second heater layer such as the second redundant heater portion. Therefore, it is possible to more effectively suppress the temperature of the ceramic span from becoming uneven by releasing the heater from the cavity, as compared with the case where the arc heater portion is formed on the first heater layer.

(4) In the electrostatic chuck, the ceramic span is provided with a first fin-through hole penetrating in the first direction, the cavity penetrating the base plate in the first direction, And a second pin through hole communicating with the pin through hole.

According to the present electrostatic chuck, it is possible to suppress the temperature of the ceramic span from becoming uneven due to the high temperature of the portion near the through-hole of the lift pin in the ceramic span.

(5) In the electrostatic chuck, the ceramic span is provided with a gas discharge hole along the first direction, the cavity penetrates the base plate in the first direction, and communicates with the gas discharge hole A gas flow path may be provided.

According to the present electrostatic chuck, it is possible to suppress the temperature of the ceramic span from becoming uneven due to the high temperature of the portion near the gas flow path in the ceramic span.

(6) The electrostatic chuck may further include an electrode provided inside the ceramic span, and the cavity may be a receiving hole for receiving a connection terminal electrically connected to the electrode.

According to the present electrostatic chuck, it is possible to suppress the temperature of the ceramic span from becoming uneven due to the high temperature of the portion near the receiving hole of the connection terminal.

(7) In the electrostatic chuck, the second heater layer may not overlap the cavity when viewed in the first direction.

According to the present electrostatic chuck, it is possible to suppress the temperature of the ceramic span from becoming uneven due to the high temperature of the portion near the cavity in the ceramic span as compared with the case where the second heater layer overlaps the cavity.

The technique disclosed in this specification can be realized in various forms, and can be realized in the form of, for example, a method of arranging a heater of an electrostatic chuck and a semiconductor device having an electrostatic chuck.

Fig. 1 is a perspective view showing the external configuration of the electrostatic chuck 10 in the first embodiment. Fig.
2 is an explanatory view showing the XY plane configuration on the upper side of the electrostatic chuck 10. Fig.
3 is an explanatory view showing the XZ cross-sectional configuration of the electrostatic chuck 10 at the position III-III in Fig.
4 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10 at a position IV-IV in Fig.
5 is an explanatory diagram showing an XY sectional configuration of the electrostatic chuck 10 at the V-V position in FIG.
6 is an explanatory diagram showing an XY cross-sectional configuration of the electrostatic chuck 10 at a position VI-VI in FIG.
7 is an explanatory view showing the XY sectional configuration of the electrostatic chuck 10 at the position VII-VII in FIG.
8 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10 at VIII-VIII position in FIG.
Fig. 9 is an explanatory diagram showing an XY sectional configuration of the electrostatic chuck 10 at the IX-IX position in Fig. 3; Fig.
10 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10 at the X-X position in Fig.
11 is an explanatory view showing an XZ cross-sectional configuration of the electrostatic chuck 10 at XI-XI position in Fig. 2. Fig.
12 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10A in the second embodiment.

A. First Embodiment:

A-1. Configuration of Electrostatic Chuck 10:

2 is an explanatory view showing an XY plane configuration on the upper side of the electrostatic chuck 10, and Fig. 3 is a cross-sectional view taken along the line III-III in Fig. 2 Sectional structure of the electrostatic chuck 10 at a position shown in Fig. In each figure, XYZ axes orthogonal to each other for specifying directions are shown. In this specification, the Z-axis positive direction is referred to as an 'upper direction' and the Z-axis direction is referred to as a 'lower direction' for convenience. However, the electrostatic chuck 10 may be provided in a direction different from such a direction. The same is applied to FIG. 4 and later.

The electrostatic chuck 10 is an apparatus for holding and fixing an object (for example, a wafer W) by electrostatic attraction. The electrostatic chuck 10 includes a ceramic span 100, a base plate 200, and an adhesive layer 300. The ceramic span 100 and the base plate 200 are arranged side by side in a predetermined arrangement direction (vertical direction (Z-axis direction) in this embodiment). The adhesive layer 300 is formed between the lower surface of the ceramic span 100 (hereinafter referred to as a "first bonding surface 102") and the upper surface of the base plate 200 (hereinafter referred to as a "second bonding surface 202" And the ceramic span 100 is bonded to the base plate 200. The adhesive layer 300 is formed of, for example, a thermosetting adhesive agent. The wafer W is placed on the front surface (upper surface) (hereinafter referred to as the "adsorption surface 104") of the wafer W. The arrangement direction (vertical direction) corresponds to the "first direction" And the surface (lower surface) of the base plate 200 opposite to the ceramic span 100 is referred to as "bottom surface 204 ".

The ceramic span 100 is a circular flat plate member, and is formed of ceramics (for example, alumina or aluminum nitride). An electrode 400 and a heater 500 are provided inside the ceramic span 100. The electrode 400 is formed of, for example, tungsten or molybdenum. When a voltage is applied to the electrode 400 from a power source (not shown), an electrostatic attraction is generated in the electrode 400, and the wafer W is attracted and fixed to the attracting surface 104 by the electrostatic attraction. The heater 500 is constituted by a resistance heating element such as tungsten or molybdenum and the ceramic span 100 is heated by the heater 500 and disposed on the absorption surface 104 of the ceramic span 100 The wafer W is warmed.

The base plate 200 is a circular flat plate member having a diameter larger than that of the ceramic span 100, and is formed of a metal such as aluminum or aluminum alloy, for example. The refrigerant flow path 210 is formed in the base plate 200 and the refrigerant CF flows into the refrigerant flow path 210 to cool the base plate 200 and the adhesive layer 300 in the base plate 200, So that the ceramic span 100 is cooled.

A plurality of (three in this embodiment) pin through holes 12 extending in the vertical direction from the ceramic span 100 to the base plate 200 are formed in the electrostatic chuck 10. A lift pin (not shown) for moving the wafer W placed on the ceramic span 100 up and away from the suction surface 104 of the ceramic span 100 is movably inserted into each of the pin through holes 12 do. The three pin through-holes 12 are arranged at regular intervals on an imaginary circle centered on a central axis passing through the center position of the electrostatic chuck 10, parallel to the Z direction. Three holes penetrating in the vertical direction are formed in the respective layers (the ceramic span 100, the base plate 200, and the adhesive layer 300) constituting the electrostatic chuck 10, The holes are vertically connected to each other to form the respective pin through-holes 12. In the following description, the holes formed in the respective layers of the electrostatic chuck 10 to form the pin through holes 12 may also be referred to as the pin through holes 12. The 'pin through hole (12)' corresponds to the 'first pin through hole' and the 'second pin through hole' in the claims.

A-2. Detailed Configuration of Ceramic Span 100:

As shown in Figs. 1 to 3, the ceramic span 100 is a ceramics sintered body in which a plurality of disk-shaped (seven in this embodiment) ceramic layers 110 to 170 are arranged side by side in the arrangement direction. Hereinafter, the seven ceramic layers 110 to 170 are sequentially referred to as "first ceramics layer 110 "," second ceramic layer 120 " Is referred to as "seventh ceramics layer 170 ".

Fig. 4 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10 at the position IV-IV in Fig. 3, and the upper surface 121 of the second ceramics layer 120 is shown. 5 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10 at the V-V position in FIG. 3, and the upper surface 131 of the third ceramic layer 130 is shown. 6 is an explanatory view showing an XY cross-sectional configuration of the electrostatic chuck 10 at a position VI-VI in FIG. 3, and an upper surface 141 of the fourth ceramics layer 140 is shown. 7 is an explanatory diagram showing an XY sectional configuration of the electrostatic chuck 10 at a position VII-VII in FIG. 3, and an upper surface 151 of the fifth ceramic layer 150 is shown. 8 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10 at VIII-VIII position in FIG. 3, and the top surface 161 of the sixth ceramics layer 160 is shown. FIG. 9 is an explanatory diagram showing an XY sectional configuration of the electrostatic chuck 10 at the IX-IX position in FIG. 3, and the upper surface 171 of the seventh ceramics layer 170 is shown.

2 to 5, a plurality (four in this embodiment) of the ceramic span 100 extending in the vertical direction from the first ceramics layer 110 to the third ceramic layer 130 are formed on the ceramic span 100, 1 gas holes 14 are formed. Each first gas hole 14 flows between the wafer W and the adsorption face 104 of the ceramic span 100 to constitute a flow path of an inert gas (for example, helium gas) for cooling the wafer W do. The four first gas holes 14 are arranged at equal intervals on an imaginary circle having a diameter smaller than that of the imaginary circle in which the three pin through holes 12 are arranged with the central axis as the center. Four holes are formed in the respective ceramic layers 110 to 130 so as to penetrate in the vertical direction. The holes formed in the respective layers and corresponding to each other vertically communicate with each other to constitute the first gas hole 14. [ In the following description, the holes formed in the respective ceramic layers 110 to 130 for constituting the first gas holes 14 may also be referred to as the first gas holes 14. The first gas hole 14 corresponds to the "gas discharge hole" in the claims.

A plurality of (four in this embodiment) second gas holes 16 extending in the vertical direction from the first ceramic layer 110 to the third ceramic layer 130 are formed in the ceramic span 100 have. Each of the second gas holes 16 also constitutes the above-mentioned flow path of the inert gas like the first gas hole 14. [ The four second gas holes 16 are arranged at equal intervals on an imaginary circle having a larger diameter than the imaginary circle in which the three pin through holes 12 are arranged with the central axis as the center. The second gas holes 16 are formed in the respective ceramic layers 110 to 130 so that the holes corresponding to each other communicate with each other in the vertical direction. In the following description, the holes formed in the respective ceramic layers 110 to 130 for constituting the second gas holes 16 may also be referred to as the second gas holes 16. [ The second gas hole 16 corresponds to a "gas discharge hole" in the claims.

As shown in Fig. 4, a plate-shaped electrode 400 is disposed on the upper surface 121 of the second ceramics layer 120. As shown in Fig. The electrode 400 has a larger diameter than an imaginary circle in which three pin through holes 12 are arranged with the central axis as the center and a circular shape with a smaller diameter than an imaginary circle in which four second gas holes 16 are arranged. to be. The electrode 400 is formed with a hole penetrating in the vertical direction and constituting the first gas hole 14 and the fin through hole 12, respectively. 3 to 8, the upper end of the electrode vias 132 penetrating from the second ceramics layer 120 to the sixth ceramics layer 160 in the up-and-down direction is formed on the lower surface of the electrode 400 And are electrically connected.

6, the upper surface 141 of the fourth ceramics layer 140 is provided with an annular first gas groove (not shown) which overlaps an imaginary circle in which four first gas holes 14 are arranged when viewed in the Z direction, (See Fig. 3). The first gas holes 14 are formed in the first gas holes 14, respectively. The first gas grooves 142 are formed in the upper and lower surfaces of the fourth ceramic layer 140 to the seventh ceramic layer 170, the adhesive layer 300, and the base plate 200, as shown in FIGS. 3 and 6 to 9, To the first gas inlet hole (143) passing through the first gas inlet hole (143). An annular second gas groove 144 is formed on the upper surface 141 of the fourth ceramics layer 140 so as to overlap with an imaginary circle in which four second gas holes 16 are arranged when viewed in the Z direction And communicates with each of the second gas holes 16 (see FIG. 3). 6 to 9, the second gas grooves 144 penetrate vertically from the fourth ceramics layer 140 to the seventh ceramics layer 170, the adhesive layer 300, and the base plate 200 And the second gas inlet hole 145 is formed in the second gas inlet hole 145. The first gas inlet hole 143 and the second gas inlet hole 145 formed in the base plate 200 correspond to the "gas channel" in the claims.

7 and 8, the heater 500 is formed on the fifth ceramics layer 150 and the sixth ceramics layer 160. As shown in Fig. The structure of the heater 500 will be described later.

As shown in Figs. 3 and 9, at the positions corresponding to the vias 132 for the electrodes of the seventh ceramics layer 170, the adhesive layer 300 and the base plate 200, electrode terminal holes 172 Is formed. An electrode terminal 174 is accommodated in the electrode terminal hole 172 and the upper end of the electrode terminal 174 is electrically connected to the lower end of the electrode via 132 through the first metallization layer 176 Respectively. The electrode terminal hole 172 corresponds to the "receiving hole" in the claims, and the electrode terminal 174 corresponds to the "connection terminal" in the claims. A heater terminal hole 182 penetrating through the seventh ceramics layer 170, the adhesive layer 300 and the base plate 200 at a position corresponding to a heater via 156 to be described later is formed in the vertical direction . The heater terminal 184 is accommodated in the heater terminal hole 182 and the upper end of the heater terminal 184 is electrically connected to the lower end of the heater via 156 through the second metallization layer 186 Respectively.

A-3. Detailed configuration of the base plate 200:

10 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10 at the X-X position in Fig. 3, and shows the internal structure of the base plate 200. Fig. The base plate 200 has an upper wall constituting the second abutment surface 202, a lower wall constituting the bottom surface 204, and an annular peripheral wall 206. An inner space is formed by the upper wall, the lower wall, and the peripheral wall 206 of the base plate 200. A support portion 208 positioned at a central position in the inner space of the base plate 200 and angular holes 12, 143, 145, 172 and 182 (hereinafter referred to as "cavities" A plurality of tubular portions 209 each extending from the upper wall to the lower wall of the base plate 200. The space defined by the peripheral wall 206 and the cylindrical portion 209 is the refrigerant passage 210. A lower wall of the base plate 200 is provided with a coolant supply hole 212 for supplying coolant CF from the outside into the coolant passage 210 and a coolant supply hole 212 for discharging the coolant CF from the coolant passage 210 to the outside A hole 214 is formed.

A-4. Detailed configuration of the heater 500:

FIG. 11 is an explanatory view showing an XZ cross-sectional configuration of the electrostatic chuck 10 at positions XI-XI in FIG. 2 and the like. 7, FIG. 8 and FIG. 11, the heater 500 includes a main heater layer 510 and a sub heater layer 520. The main heater layer 510 corresponds to the 'second heater layer' in the claims and the sub heater layer 520 corresponds to the 'first heater layer' in the claims. 3, 7, and 11, the main heater layer 510 is disposed on the upper surface 151 of the fifth ceramics layer 150. As shown in FIG. The main heater layer 510 has a plurality of (ten in this embodiment) main heater wires 512.

The ten main heater wires 512 are arranged so as to be substantially concentrically arranged sequentially from the center side of the fifth ceramic layer 150. The plurality of main heater wires 512 are arranged at substantially equal intervals in the radial direction of the ceramic span 100 (hereinafter, simply referred to as "radial direction"). Further, the diametrical direction corresponds to the " second direction " in the claims. In addition, the distance between adjacent main heater wires 512 in the radial direction is almost uniform over the entire circumference. In the circumferential direction of the ceramic span 100 (hereinafter simply referred to as "circumferential direction"), adjacent main heater wires 512 are spaced apart from each other. Hereinafter, ten main heater wires 512 are referred to as "first main heater wire 512A "," second main heater wire 512B " Quot; the tenth main heater wire 512J ". The main heater wire 512 corresponds to the 'redundant heater portion' and the 'arc heater portion' in the claims and both ends of the main heater wire 512 correspond to the 'heater end' do.

The above-described three pin through holes 12, the first gas inlet hole 143, the second gas inlet hole 145, and the electrode vias (not shown) formed in the fifth ceramics layer 150 132 are located between adjacent main heater wires 512 in the circumferential direction. Specifically, the pin through-hole 12 located on the X-axis positive side is located between the fourth main heater line 512D and the fifth main heater line 512E, the eighth main heater line 512H, And is located between the heater wires 512I. The pin through hole 12 positioned on the Y axis positive side is connected to the second main heater wire 512B and the third main heater wire 512C and between the fifth main heater wire 512E and the sixth main heater wire 512F As shown in FIG. The pin through hole 12 positioned on the Y axis direction side is located between the third main heater line 512C and the fourth main heater line 512D and between the seventh main heater line 512G and the eighth main heater line 512H. The first gas inlet hole 143 is located between the first main heater wire 512A and the second main heater wire 512B. The second gas inlet hole 145 is located between the ninth main heater wire 512I and the tenth main heater wire 512J. The electrode vias 132 are located between the sixth main heater wire 512F and the seventh main heater wire 512G. As described above, the main heater wire 512 is arranged so as to avoid forming positions of the holes 12, 143, 145 and the electrode vias 132.

One end of the first main heater wire 512A and one end of the tenth main heater wire 512J are provided with heater vias (not shown) extending vertically from the fifth ceramic layer 150 to the sixth ceramics layer 160 156 are electrically connected to each other (see Fig. 3).

3, 7, 8, and 11, the sub heater layer 520 is disposed on the upper surface 161 of the sixth ceramics layer 160. The sub heater layer 520 includes a plurality (nine in this embodiment) of sub heater wires 522. Each sub heater wire 522 connects the ends of the main heater wires 512 adjacent to each other in the circumferential direction when viewed from the Z direction and connects the end of each of the holes 12, So that the formation position of the via-hole 132 is avoided. Hereinafter, the nine sub heater lines 522 are referred to as "first sub heater wire 522A "," second sub heater wire 522B " Quot; the ninth sub heater wire 522I ". Since the sub heater wire 522 overlaps a center line of the ceramic span 100 and a virtual straight line passing through the cavity and is closest to the cavity, the 'redundant heater portion', the ' Quot; portion ". The main heater wire 512 adjacent to the sub heater wire 522 in the radial direction corresponds to the "second redundant heater portion" in the claims.

More specifically, the first sub heater wire 522A disposed in the vicinity of the first gas inlet hole 143 connects one end of the first main heater wire 512A and one end of the second main heater wire 512B And is formed into an arc shape protruding toward the center of the fifth ceramics layer 150 with the first gas inlet hole 143 as the center. The fourth sub heater wire 522D located in the vicinity of the pin through hole 12 located on the X axis positive side connects one end of the fourth main heater wire 512D and one end of the fifth main heater wire 512E And is formed in an arc shape protruding toward the center of the fifth ceramic layer 150 with the pin through hole 12 as the center. The eighth sub heater wire 522H positioned in the vicinity of the pin through hole 12 located on the X axis positive side connects one end of the eighth main heater wire 512H and one end of the ninth main heater wire 512I And is formed into an arc shape protruding toward the periphery of the fifth ceramics layer 150 with the pin through hole 12 as the center.

The second sub heater wire 522B located in the vicinity of the pin through hole 12 located on the Y axis positive side connects one end of the second main heater wire 512B and one end of the third main heater wire 512C And is formed in an arc shape protruding toward the center of the fifth ceramic layer 150 with the pin through hole 12 as the center. The fifth sub heater wire 522E positioned in the vicinity of the pin through hole 12 located on the Y axis positive side connects one end of the fifth main heater wire 512E and one end of the sixth main heater wire 512F And is formed into an arc shape protruding toward the peripheral edge of the fifth ceramics layer 150 with the pin through hole 12 as the center. The sixth sub heater wire 522F disposed in the vicinity of the electrode vias 132 connects one end of the sixth main heater wire 512F and one end of the seventh main heater wire 512G, And is formed in an arc shape protruding toward the periphery of the fifth ceramics layer 150 with the vias 132 as the center.

The third sub heater wire 522C located in the vicinity of the pin through hole 12 positioned on the Y axis direction side is connected to one end of the third main heater wire 512C and one end of the fourth main heater wire 512D And is formed into an arc shape protruding toward the center of the fifth ceramic layer 150 with the pin through hole 12 as the center. The seventh sub heater wire 522G located in the vicinity of the pin through hole 12 located on the Y axis direction side is connected to one end of the seventh main heater wire 512G and one end of the eighth main heater wire 512H And is formed into an arc shape protruding toward the peripheral edge of the fifth ceramics layer 150 with the pin through hole 12 as the center. The ninth sub heater wire 522I disposed in the vicinity of the second gas inlet hole 145 connects one end of the ninth main heater wire 512I and one end of the tenth main heater wire 512J, And is formed in an arc shape protruding toward the peripheral edge of the fifth ceramics layer 150 with the second gas inlet hole 145 as a center.

As shown in Fig. 11, both ends of each sub heater wire 522 are electrically connected to each of a pair of adjacent main heater wires 512 in the circumferential direction through the via vias 156. As described above, the main heater wire 512 and the sub heater wire 522 are connected in series via the heater vias 156. Specifically, as shown in Fig. 11, one end of the ninth sub heater wire 522I is electrically connected to one end of the ninth main heater wire 512I via the via vias 156, And the other end of the second heater wire 522I is electrically connected to one end of the tenth main heater wire 512J through the heater via.

A-5. Effects of the present embodiment:

As described above, the base plate 200 is provided with cavities 12, 143, 145, 172 and 182, and the refrigerant passage 210 can not be formed in the cavities. Therefore, in the ceramic span 100, the cooling effect by the refrigerant is low in the portion close to the cavity. Therefore, in the ceramic span 100, when the heater wires are arranged at equal intervals in the radial direction at the portion close to the cavity as in the portion apart from the cavity, the portion close to the cavity becomes high temperature, There is a possibility that the temperature of the adsorption surface 104 becomes uneven in the surface direction.

In contrast, according to the present embodiment, the sub heater wire 522 located in the portion closest to the cavity in the radial direction is disposed in the sixth ceramics layer 160, and next to the sub heater wire 522 The main heater line 512 near the cavity is disposed in the fifth ceramic layer 150 different from the sixth ceramic layer 160. Therefore, the distance between the sub heater wire 522 and the main heater wire 512 is smaller than the distance between the sub heater wire 522 and the main heater wire 512 (the fifth ceramic layer 150) It becomes longer. Since the distance from the adsorption surface 104 to the sub heater wire 522 is different from the distance from the adsorption surface 104 to the main heater wire 512, the sub heater wire 522 and the main heater wire 512, The total amount of heat transferred to the adsorbing surface 104 can be reduced. Therefore, it is possible to suppress the temperature of the ceramic span 100 from becoming uneven due to the high temperature of the portion close to the cavity.

Further, when the heater 500 is arranged to avoid cavitation when viewed in the Z direction, the main heater wire 512 and the sub heater wire 522 may become close to each other and become high temperature. For example, the eighth sub heater wire 522H and the ninth main heater wire 512I are closer to each other. However, in the present embodiment, the main heater wire 512 and the sub heater wire 522 are disposed on different layers. Therefore, as compared with the case where the main heater wire 512 and the sub heater wire 522 are arranged in the same layer, the main heater wire 512 and the sub heater wire 522 are arranged close to each other, It is possible to suppress the temperature of the substrate 100 from becoming partially high.

The main heater wire 512 (the arc heater portion) adjacent to the sub heater wire 522 in the circumferential direction and the main heater wire 512 adjacent in the radial direction are arranged in the same fifth ceramic layer 150 . For example, the ninth main heater wire 512I, which is adjacent to the sixth main heater wire 512F and the like, radially adjacent to the sixth sub heater wire 522F in the circumferential direction is connected to the fifth ceramics layer 150, Respectively. Therefore, unevenness of the temperature of the ceramic span 100 can be more effectively suppressed by releasing the heater 500 from the cavity, as compared with the case where the arc heater portion is formed on the first heater layer.

3 and 7, the main heater wire 512 does not overlap the cavity of the base plate 200 when viewed in the Z direction. This makes it possible to prevent the temperature of the ceramic span 100 from becoming uneven due to the high temperature of the portion close to the cavity of the ceramic span 100 as compared with the case where the main heater wire 512 overlaps the cavity of the base plate 200 Can be suppressed.

The sub heater wire 522 closest to the cavity is arranged in the ceramic layer farther from the adsorption surface 104 than the main heater wire 512 next to the sub heater wire 522. Therefore, compared with the case where the sub heater wire 522 is disposed on the ceramics layer nearer to the adsorption face 104 than the main heater wire 512, the portion near the cavity of the ceramic span 100 is heated to a high temperature The temperature of the ceramic span 100 can be more effectively suppressed from becoming uneven. When viewed in the Z direction, the entire arrangement area of the main heater wires 512 is wider than the arrangement area of the entire sub heater wires 522. Therefore, if the main heater wire 512 having a relatively large arrangement area is disposed at a position closer to the adsorption surface 104 than the sub heater wire 522 having a relatively small arrangement area as in the present embodiment, The entire heating value can be efficiently transferred to the adsorption face 104.

B. Second Embodiment:

12 is an explanatory view showing an XY sectional configuration of the electrostatic chuck 10A of the second embodiment. The same components as those of the electrostatic chuck 10 of the first embodiment among the components of the electrostatic chuck 10A of the second embodiment are denoted by the same reference numerals and the description thereof is omitted.

A heater 500A is provided inside the ceramic span 100A provided in the electrostatic chuck 10A and the heater 500 includes a main heater layer 530 and a sub heater layer 540. [ The main heater layer 530 corresponds to the second heater layer in the claims, and the sub heater layer 540 corresponds to the first heater layer in the claims. 12, the main heater layer 530 is disposed on the upper surface 151A of the fifth ceramics layer 150A. The main heater layer 530 is provided with a plurality of (two in this embodiment) main heater wires 532 that are not electrically connected to each other but can independently control the temperature. Both ends of the first main heater wire 532A located on the peripheral side of the fifth ceramic layer 150A are electrically connected to the via vias 156A, respectively. One end of the second main heater wire 532B located at the center of the fifth ceramics layer 150A is also electrically connected to the upper end of the heater via 156A.

The lower end of each heater via 156A is electrically connected to one end of each of the three conductive patterns 544 formed in the sixth ceramic layer (not shown) located below the fifth ceramic layer 150A. The other end of each conduction pattern 544 is located at the center of the sixth ceramic layer and is electrically connected to one of the four heater terminal holes 552 formed in the base plate 200 via vias And is electrically connected to a terminal (not shown). In addition, the four heater terminal holes 552 are arranged at equal intervals on an imaginary circle centered on the central axis when viewed in the Z direction.

The sub heater layer 540 includes a sub heater line 542 disposed on the upper surface of the sixth ceramics layer. The sub heater wire 542 is located on the center side of the ceramic span 100A when viewed in the Z direction and arranged to avoid the four heater terminal holes 552. [ Specifically, the sub heater wire 542 is annularly arranged in the area between the four heater terminal holes 552 and the main heater wire 532. One end of the sub heater wire 542 is electrically connected to the second main heater wire 532B via the via vias 154A and the other end of the sub heater wire 542 is accommodated in the heater terminal hole 552 through a via And is electrically connected to the heater terminal.

As described above, according to the present embodiment, the sub heater wire 542 closest to the four heater terminal holes 552 is disposed in the sixth ceramic layer, and the four heater terminal holes 552 are next And the second main heater line 532B is disposed in the fifth ceramics layer 150A. Accordingly, the distance between the sub heater wire 542 and the second main heater wire 532B becomes longer than in the case where the sub heater wire 542 and the second main heater wire 532B are formed on the same layer. Since the distance from the adsorption face 104 to the sub heater wire 542 is different from the distance from the adsorption face 104 to the second main heater wire 532B, the distance between the sub heater wire 542 and the main heater wire 532B to the adsorption face 104 can be reduced. Therefore, it is possible to suppress the temperature of the ceramic span 100 from becoming uneven due to the high temperature of the portion near the four heater terminal holes 552. [

C. Modifications:

The technique disclosed in this specification is not limited to the above-described embodiment, and various modifications may be made without departing from the gist of the invention. For example, the following modifications are possible.

Although the sub heater wire 522 is disposed on the ceramic layer farther from the adsorption face 104 than the main heater wire 512 in the above embodiment, the sub heater wire 522 is disposed on the main heater wire 512, It may be arranged in the ceramic layer near the adsorption face 104 as compared with the adsorption face 104.

In the above embodiment, a part of the main heater wire 512 may overlap the cavity of the base plate 200 when viewed in the Z direction.

The entirety of the heaters 500 and 500A is provided inside the ceramic span 100. At least a part of the heaters 510 and 530 may be provided outside the ceramics span 100 The lower surface of the span 100).

(The through-hole 12 or the like) penetrating through the base plate as the cavity of the base plate 200 is exemplified in the above embodiment, the present invention is not limited to this, and the recessed portion Hole having a bottom portion, for example, a space for accommodating the temperature sensor).

In the above embodiment, the ceramic span 100 is of a single pole type and includes one electrode 400. However, the ceramic span 100 is provided with a pair of electrodes employing a double pole type .

In the above embodiment, the number of the ceramic layers constituting the ceramic span 100 is merely an example, and the number of the ceramic layers can be appropriately determined in accordance with the functions required of the ceramic span 100 and the like.

10,10A - Electrostatic chuck 12 - Pin through hole
14 - first gas hole 16 - second gas hole
100,100 A - Ceramic span 102 - Joint face
104 - adsorption surface 110 - 170 - ceramic layer
132 - Via for electrode 142 - First gas groove
143 - first gas inlet hole 144 - second gas groove
145 - second gas inlet holes 154A, 156, 156A - vias for heater
172 - terminal hole for electrode 174 - terminal for electrode
176,186 - Metallization layer 182,552 - Terminal hole for heater
184 - Heater terminal 200 - Base plate
202 - joint surface 204 - bottom surface
206 - circumferential wall 208 - support
209 - tubular part 210 - refrigerant flow path
212 - Refrigerant supply hole 214 - Refrigerant discharge hole
300 - adhesive layer 400 - electrode
500,500A - Heater 510,530 - Main heater layer
512 (512A to 512J), 532 (532A, 532B) - Main heater wire
520, 540 - a sub heater layer 522 (522A - 522I), 542 - a sub heater wire
544 - conduction pattern CF - refrigerant
W - Wafer

Claims (7)

(100, 100A) provided with heaters (500, 500A) constituted of a resistance heating element and formed by ceramics and a plurality of ceramic spans (100, 100A) arranged on one surface side in the first direction of the ceramic spans And a base plate (200) having a refrigerant passage (210) formed therein,
The base plate 200 is provided with cavities 12, 143, 145, 172 and 182 at positions different from the refrigerant passage 210 when viewed in the first direction,
The heater (500, 500A)
The overlapping heater portions 512, 532, and 522, which are portions overlapping with the imaginary straight line passing through the cavities 12, 143, 145, 172, and 182 and the centers of the ceramic spans 100 and 100A in the first direction, , 542)
A first redundant heater portion (522,542) closest to said cavity (12,143,145, 172,182), as viewed in said first direction, of said plurality of redundant heater portions (512,532,522,542) A first heater layer 520 and a second heater layer 540,
The second heater layers 510 and 530 are electrically connected to at least a portion of the first heater layers 520 and 540 and the first heater layers 520 and 540 are different from the first heater layers 520 and 540 143, 145, 172, 182 in a second direction of the plurality of overlapping heater portions 512, 532, 522, 542 parallel to the imaginary straight line when viewed in the first direction, Of the first overlapping heater portion (522, 542) next to the first overlapping heater portion (522, 542) and next to the first overlapping heater portion (522, 542) And a second heater layer (510, 530) including two overlapping heater portions (512, 532).
The method according to claim 1,
The first heater layer 520 and the second heater layer 540 are separated from the other surface of the ceramic span 100 or 100A opposite to the one surface of the second heater layer 510 or 530, chuck.
The method according to claim 1 or 2,
The second heater layers 510 and 530 are circular arc heater portions 512 extending in an arc shape along the direction of the center of the ceramic spans 100 and 100A when viewed in the first direction, Further comprising an arc heater portion (512) having a pair of heater ends arranged in the direction orthogonal to the imaginary straight line and sandwiching the cavities (12, 143, 145, 172, 182)
The first redundant heater portions 522 and 542 extend from one side of the pair of heater ends to the other while avoiding the cavities 12, 143, 145, 172 and 182 when viewed in the first direction And is electrically connected to the pair of heater ends.
The method according to claim 1,
The ceramic spans 100 and 100A have first fin-through holes 12 penetrating in the first direction,
Wherein the cavity (12) is a second pin through-hole (12) that penetrates the base plate (200) in the first direction and communicates with the first pin through hole (12) .
The method according to claim 1,
Gas discharge holes (14, 16) are formed in the ceramic span (100, 100A) along the first direction,
Wherein the cavities (143, 145) are gas passages passing through the base plate (200) in the first direction and communicating with the gas discharge holes (14, 16).
The method according to claim 1,
And an electrode 400 provided inside the ceramic span 100, 100A,
Wherein the cavity (172) is a receiving hole (172) for receiving a connection terminal (174) electrically connected to the electrode (400).
The method according to claim 1,
Wherein the second heater layer (510, 530) is not overlapped with the cavity (12, 143, 145, 172, 182) when viewed in the first direction.

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