KR20040073087A - Wafer holder - Google Patents

Abstract

PURPOSE: A wafer holder is provided to enhance the productivity by reducing damage and scratches of a wafer in a process for fixing the wafer to a wafer holder. CONSTITUTION: A plurality of pads(130) are arranged on the surface of a plate(110) in order to support a wafer. A plurality of guide pins are installed at a predetermined position on the plate opposite to a lateral part of the wafer. The guide pins are used for aligning the wafer supported on the pads at a predetermined loading point. The guide pins are located vertically to the plate. One of the guide pins is inserted into a notch(142), which is formed on the lateral part of the wafer by moving the wafer. Each external part of the guide pins is formed with plastics.

Description

Wafer holder {Wafer holder}

The present invention relates to a wafer holder, and more particularly, to a wafer holder on which a wafer is placed and which holds the placed wafer.

In general, the manufacture of a semiconductor device is a process of obtaining a desired semiconductor device by forming a multilayer film on a single crystal wafer according to a desired circuit pattern, and is a deposition process, a photolithography process, an oxidation process, an etching process, an ion implantation process, and a metal wiring process. A series of processes such as these are carried out in accordance with each step. In addition to these unit processes, measurement processes such as pattern size, ion implantation concentration, and number of particles are performed.

When performing the unit processes, the wafer must be loaded into process equipment or metrology equipment. At this time, the wafer is generally moved to the upper surface of the holder provided in the equipment by using a transfer device such as a robot arm. Alternatively, the holder may be loaded into the device after the wafer is fixed to the holder according to the characteristics of the device.

An example of a semiconductor device including a holder on which a wafer is placed and holding the wafer is disclosed in US Pat. No. 5,820,329 to Derbinsdki et al., Et al.

Hereinafter, the wafer holder which is included in the scanning electron microscope (SEM) which measures the line width of a pattern, etc., and fixes the wafer in order to move a wafer into the chamber of the said scanning electron microscope is demonstrated.

1 is a schematic cross-sectional view for explaining the structure of a wafer holder according to the prior art.

Referring to FIG. 1, a wafer holder is provided with a plate 10 on which a wafer 40 is placed. The upper surface of the plate 10 is provided with a plurality of guide pins 20 for fixing the wafer 40. The guide pin 20 is in contact with the side surface of the wafer 40 placed on the plate 10 to fix the wafer 40 on the plate 10. The guide pin 20 is entirely formed of a metal of copper material.

Guide pin 20 is a screw 22 to be fastened by screwing the plate 10, the outer side provided to surround the inner ring 24 and the inner ring 24 coupled to the screw 22 Ring 26. Engage the inner ring 24 to surround the screw portion below the head in the screw 22. The outer ring 26 included in the guide pin 20 rotates horizontally by a force applied from the outside. In addition, a bearing 28 is included between the inner ring 24 and the outer ring 26 to reduce friction generated during the horizontal rotation. The outer ring 26 has an inclined tapered structure in which the outer surface is wider upward and narrower toward the lower side.

By the way, when fixing the wafer 40 to the wafer holder having the above configuration, unexpected defects frequently occur. For example, when the notch portion of the wafer 40 does not contact the guide pin 20 correctly, an alignment error may occur because the notch does not appear in the previously recognized alignment region on the optical microscope.

In addition, since the portion where the side of the guide pin 20 and the wafer 40 contact, that is, the outer ring 26 has a tapered structure, the wafer 40 is unloaded in the vertical direction of the plate 110. Particles are generated by the friction between the side of the outer ring and the outer ring 26. In particular, since the material of the guide pin 20 is a weak copper material, particles are more likely to occur. The particles will contaminate the wafer 40. The particles may move again due to the pressure difference due to the loading and unloading of the wafer 40, and may cause contamination of the chamber. Therefore, new wafers 40 loaded afterwards may be contaminated. If the chamber is contaminated, clean operation for removing the particles takes about 3 to 4 hours, adversely affecting the production of the product.

When the guide pin 20 and the side surface of the wafer 40 are in strong contact with each other, there is also a problem in that the edge portion of the wafer 40 is broken or scratches are generated.

An object of the present invention for solving the above problems is to provide a wafer holder for fixing the wafer without causing a defect in the wafer.

1 is a schematic cross-sectional view for explaining the structure of a wafer holder according to the prior art.

2 is a schematic plan view for explaining the structure of a wafer holder according to an embodiment of the present invention.

3 is a cross-sectional view illustrating the structure of the wafer holder shown in FIG. 2.

4 is an exploded perspective view of the guide pin shown in FIG. 2.

5 is a cross-sectional view illustrating a structure of a wafer holder according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

110, 210: plate 120, 220: guide pin

122, 222: screw 124, 224: inner ring

126, 226: outer ring 128, 228: ball bearing

130, 230: pad 140, 240: wafer

142: notch 150: bellows

260: coating film

In order to achieve the object of the present invention the present invention is to face the plate, a plurality of pads disposed on the plate for supporting the wafer and the side of the wafer supported on the plurality of pads on the upper surface of the plate A wafer holder is disposed and includes a plurality of guide pins for aligning wafers supported on the plurality of pads at predetermined wafer loading points. The guide pins are perpendicular to the plate and move the wafer so that one of the guide pins is inserted into a notch formed on the side of the wafer, and the outer portions of the guide pins in contact with the wafer are each made of plastic. It is made of material.

The wafer holder according to the present invention configured as described above reduces the friction between the side of the wafer and the guide pin during the wafer unloading because the guide pin is perpendicular to the plate, and the guide pin is made of a plastic material, By forming a rubber or Teflon coated surface on the outer portion of the guide pin, the impact on the wafer when the guide pin contacts the side of the wafer is reduced. Therefore, the defect generated in the wafer by the guide pin can be reduced.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a schematic plan view for explaining the structure of a wafer holder according to an embodiment of the present invention, Figure 3 is a cross-sectional view for explaining the structure of the wafer holder shown in FIG.

2 and 3, a plate 110 having a plane larger than the size of the target wafer 140 fixed to the wafer holder 100 is provided. A plurality of pads 130 directly contacting the bottom surface of the wafer 140 are attached to the upper surface of the plate 110. Since the pad 130 is provided, the bottom surface of the wafer 140 is not in direct contact with the top surface of the plate 110 but only in contact with the top surface of the pad 130, thereby reducing the contact area. It is preferable that there are at least three so as to stably support the 140.

The upper surface of the plate 110 is also provided with a plurality of guide pins 120 for fixing the wafer 140. The guide pin 120 is formed of a material of weak strength of the plastic material as a whole. The guide pin 120 has a cylindrical shape as a whole so as to be in parallel with the side surface of the wafer 140, and is preferably provided to be perpendicular to the plate 110. In addition, it is preferable that at least three guide pins 120 are also used to fix the wafer 140.

As shown in FIG. 3, the guide pin 120 surrounds the screw 122 coupled to the plate 110, the inner ring 124 and the inner ring 124 coupled to one side of the screw 122. It consists of an outer ring 126 and a ball bearing ring 128 provided between the inner ring 124 and the outer ring 126 is provided.

Specifically, referring to an exploded perspective view of the guide pin of FIG. 4, the screw 122 has a head portion 122a and a head portion 122a having grooves for use when screwing the plate 110 and the upper portion thereof. A screw portion 122b for engaging with the plate below. At this time, the stage 122a is formed in the head portion 122a. The end is formed of an upper end and a lower end, the upper end is larger than the lower end. The upper surface of the upper end is provided with a straight or cross-shaped groove.

And, the inner ring 124 is configured to surround a part of the screw portion 120b in the screw 120, the outer ring 126 is spaced apart from the inner ring 124 by a predetermined interval to surround the inner ring 124 It is composed. The height of the inner ring 124 and the outer ring 126 is preferably equal. The ball bearing 128 is provided between the inner ring 124 and the outer ring 126, and allows the outer ring 126 to rotate smoothly about the screw 122 and the inner ring 124. The ball bearing 128 may be provided insulated or double row depending on the height of the inner ring 124 and the outer ring 126. The ball bearing 128 is preferably provided with heat insulation when the height of the inner ring 124 and the outer ring 126 is low, and double row when the height.

Referring to FIG. 3, first, the inner ring 124 is coupled to surround the screw portion 122b under the head portion 122a of the screw 122, and the outer surface is spaced apart from the outer surface of the inner ring 124 by a predetermined distance. The ring 126 is disposed and assembled with guide pins 120 mounted on the plate 110 with a ball bearing 128 between the inner ring 124 and the outer ring 126.

At this time, in the assembled guide pin 120, the upper surface of the inner ring 124 and the outer ring 126 is formed to face the lower surface of the lower step formed in the head portion 122a of the screw 122. . The lower step diameter should be smaller than the inner diameter of the outer ring 126. This is to allow the outer ring 126 to rotate freely without friction with the head portion 122a of the screw 122. In addition, the diameter of the upper step is formed to have the same size as the outer diameter of the outer ring 126, so that the wafer 140 and the upper step does not collide while unloading the wafer 140.

On the other hand, it is preferable to form a slope in the side portion of the upper step. Even when the robot arm does not place the wafer 140 on the plate 110 and the wafer 140 is placed over the guide pin 120, the wafer 140 may still have the head of the screw 122. It slides down 122a and is correctly placed on the plate 110.

In the guide pin 120 assembled as described above, the screw portion 122b of the screw 122 that is not coupled to the inner ring 124 and the outer ring 126 is coupled to the plate 110. Accordingly, the inner ring 124 and the outer ring 126 and the head 122a of the screw 122 protrude upward from the plate 110.

As shown in FIG. 2, the plurality of guide pins 120 contact the side surfaces of the wafer 140 placed on the pad 130 to fix the wafer 140. Thus, at least one guide pin 120 must have a movable configuration to contact the side of the wafer 140 and the guide pins 120. To this end, the guide pin 120 may be connected to the bellows 150, which is stretched by external pressure, and configured to be movable along a predetermined path.

Preferably, only one guide pin 120a of the plurality of guide pins 120 is configured to be movable by connecting with the bellows 150, and the remaining guide pins 120b and 120c are connected to the side surface of the wafer 140. It is fixed in a predetermined position which can contact each. Accordingly, one guide pin 120a connected to the bellows 150 is moved to allow the plurality of guide pins 120a, 120b, and 120c to contact the side surface of the wafer 140. At this time, the side surface of the wafer 140 is in contact with the outer surface of the outer ring 126 provided on the guide pin 120.

When one guide pin 120a connected to the bellows 150 is moved to contact all the guide pins 120 on the plate 110 with the side surface of the wafer 140, the wafers 140 may have respective guide pins ( A predetermined force is applied to the outer ring 126 included in the 120. At this time, the outer ring 126 is rotated about the screw 122 and the inner ring 124 by the force applied to the outer ring 126. As the outer ring 126 rotates, breakage of the edge portion of the wafer 140 may be reduced. In addition, a notch contact is formed in which the notch 142 formed at the edge of the wafer 140 is caught and aligned by one guide pin 120b.

5 is a cross-sectional view illustrating a structure of a wafer holder according to another embodiment of the present invention.

Referring to FIG. 5, the portion of the wafer holder 200 except for the guide holder 220 and the wafer holder 100 of the exemplary embodiment illustrated in FIGS. 2, 3, and 4 is the same, a description thereof will be omitted. . The structure of the guide pin 220 is the same as that of the guide pin 120 of the above embodiment. Therefore, description of the structure of the guide pin 220 is also omitted.

The guide pin 220 is formed with a coating surface 260 of rubber or Teflon material on the outer surface of a metal material such as copper. That is to form a coating surface 260 on the outer surface of the outer ring (226). Since the rubber or Teflon is weaker than the wafer 240, the wafer 240 and the guide pin 220 coated with the rubber or Teflon material contact each other while the wafer 240 is fixed to the wafer holder 200. Even if it does not break or scratch. Teflon in particular depends on the load, the speed of sliding and the type of Teflon coating used, but generally has a coefficient of friction of 0.05 to 0.20. Therefore, particle generation due to friction between the guide pin 220 and the side of the wafer 240 is significantly reduced.

A process of fixing the wafer 140 to the wafer holder 100 having the above configuration based on the above embodiment will be briefly described.

First, the back surface of the target wafer 140 to be fixed to the wafer holder 100 is sucked by a robot arm (not shown), and the robot arm moves the wafer 140 onto the plate 110. Subsequently, the robot arm adsorbing the wafer 140 is lowered, and the wafer 140 adsorbed on the robot arm is placed on the upper surface of the plate 110. At this time, the wafer 140 is placed inside the guide pins 120 provided in the plate 110.

Subsequently, the wafer 140 is moved by moving one guide pin 120a connected to the bellows 150. The notch 142 of the wafer 140 contacts the guide pin 120b of one of the remaining fixed guide pins 120b and 120c so that the wafer 140 is accurately placed on the wafer holder 100. The remaining guide pins 120c prevent the wafer 140 from leaving the limit region of the wafer holder 100 while one guide pin 120a connected to the bellows 150 is moved. Accordingly, the side of the wafer 140 is in contact with the plurality of guide pins 120. That is, the guide pins 120 are in close contact with each side of the wafer 140, thereby fixing the wafer 140 to the upper surface of the plate 110.

The guide pin 120 is perpendicular to the plate 110 in a cylindrical shape as a whole. Therefore, while unloading the wafer 140 vertically, friction between the side surface of the wafer 140 and the guide pin 120 may be minimized to suppress particle generation. In addition, the guide pin 120 is formed of a plastic material as described above, or the coating surface is formed of a rubber or Teflon material. That is, the guide pin 120 is weaker than the wafer 140 to be in contact. Therefore, the guide pin 120 formed of the plastic material or the coating surface formed of rubber or Teflon material may use the guide pin 120 formed of a metal material such as copper, even though the side of the wafer 140 is strongly in contact with the side surface of the wafer 140. In comparison, the impact applied to the wafer 140 can be reduced. Therefore, breakage or scratching of the wafer 140 due to contact with the guide pin 120 can be reduced.

As described above, according to the present invention, not only the breakage or scratch of the wafer generated when the wafer is fixed to the wafer holder can be reduced, but also the particles generated on the wafer can be reduced. As defects that can occur in the wafer are reduced, yield and productivity are improved.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified without departing from the spirit and scope of the invention described in the claims below. And can be changed.

Claims (4)

plate; A plurality of pads disposed on the plate to support a wafer; And A plurality of guide pins disposed on an upper surface of the plate to face side surfaces of the wafer supported on the plurality of pads, the plurality of guide pins for aligning the wafers supported on the plurality of pads at a predetermined wafer loading point, The guide pins are perpendicular to the plate and move the wafer so that one of the guide pins is inserted into a notch formed on the side of the wafer, and the outer portions of the guide pins in contact with the wafer are each made of plastic. Wafer holder, characterized in that made of material. The method of claim 1, wherein one of the guide pins moves to align a wafer supported on the plurality of pads, and the other of the guide pins supports the side of the wafer supported on the plurality of pads. A wafer holder, which is fixed on a plate. The wafer holder according to claim 1, wherein an outer portion of each of the guide pins is rotatably provided about a central axis of each of the guide pins. The wafer holder of claim 1, wherein the outer portion of the guide pin is coated with rubber or Teflon material.