The present invention relates to a method for manufacturing a polishing head, a polishing head, and a polishing apparatus including the polishing head.
In recent years, a demand concerning flatness of a wafer such as a silicon wafer has been increased more than ever, and fabricating a wafer having higher flatness in single-side polishing has been demanded. Further, to provide a wafer having high flatness with excellent reproducibility, a polishing head including a rubber film which holds the wafer, a space section which is in contact with the rubber film, and an incompressible fluid which is sealed in the space section is used (see, e.g., Patent Literature 1).
According to such a polishing head, since a shape of a surface of the rubber film can be appropriately adjusted by the incompressible fluid, when the surface of the rubber film is appressed against an entire back surface of the wafer to press the wafer, polishing can be carried out. Consequently, a stock removal of the wafer can be uniformed on an entire polishing surface, and the wafer with high flatness can be fabricated. Further, since the shape of the surface of the rubber film which adsorbs the wafer can be controlled to be constant by the incompressible fluid, the wafer with high flatness can be provided with excellent reproducibility.
However, to uniform the shape of the surface of the rubber film which adsorbs the wafer, the incompressible fluid must be sealed in the space section in the polishing; head without mixing air in manufacture of the polishing head. That is because a pressure in a portion where the air is present is different from those in other portions when the air is mixed, the shape of the surface of the rubber film cannot be controlled to be constant, and the wafer cannot be uniformly pressed. Furthermore, when the air is mixed, a volume of the incompressible fluid which is to be sealed in the polishing head largely varies, and the shape of the polished wafer also largely varies. Thus, in manufacture of the polishing head, the air must be prevented from remaining particularly in the space section where the incompressible fluid is sealed in.
Thus, to prevent the air from being mixed, parts of the polishing head are immersed in the incompressible fluid, and the polishing head is manually assembled in the incompressible fluid in some cases. However, according to this technique, controlling an amount of the incompressible fluid to be sealed in is difficult. Moreover, since the polishing head is assembled in the incompressible fluid, workability is considerably degraded. Additionally, a polishing head which is used for polishing of a large-diameter wafer having a diameter of 300 mm or more has a large size and a very heavy weight, and hence a problem arises in a safety aspect as well as the workability. Further, when the incompressible fluid to be sealed in is harmful to human bodies, work itself is impossible.
On the other hand, as described, below, there is also a technique to assemble the polishing head in air rather than the incompressible fluid. According to this technique, first, as shown in an upper part of
Patent Literature 1: Japanese Unexamined Patent Application Publication No. 2013-166200
However, when the incompressible fluid is sealed in the space section in the polishing head by the depressurizing and sealing method, a large amount of air remains in the polishing head. For this reason, since the inlet and the outlet are provided in a central portion with a small thickness due to a structure of the polishing head, the incompressible fluid closes the outlet on an early stage before discharging the air remaining at an outer periphery of the space section, and hence the remaining air cannot be discharged.
To solve this problem, it is effective to provide the inlet and the outlet in the vicinity of the outer peripheral portion in such a manner that a distance between the inlet and the outlet becomes as large as possible. However, the outer peripheral portion of the polishing head has a large thickness from the beginning, the outer peripheral portion of the polishing head becomes thick due to a height of a coupler connected to each of the inlet and the outlet, and hence a weight of the polishing head increases. Additionally, a volume of the space section in the polishing head increases, and responsiveness of pressurization or depressurization to the wafer at the time of polishing becomes poor. Thus, providing the inlet or the outlet in the outer peripheral portion of the polishing head is not practical.
Further, to reduce an amount of the remaining air, as shown in
In view of such a problem as described above, it is an object, of the present invention to provide a method for manufacturing a polishing head, which has excellent workability, facilitates controlling an amount of an incompressible fluid, and can reduce an amount of air remaining in a space section at the time of manufacturing the polishing head having the incompressible fluid sealed in the space section.
Furthermore, it is another object, of the present invention to provide a polishing head and a polishing apparatus including the polishing head, which enable reducing an amount of air remaining in a space section having an incompressible fluid sealed therein and manufacturing a wafer having high flatness with excellent reproducibility.
To achieve the problem, the present invention provides a method for manufacturing a polishing head which includes: an annular rigid ring; an elastic film attached to a lower end surface of the rigid ring by uniform tensile force; a discoid intermediate plate coupled with an upper end surface of the rigid ring; a space section partitioned by the lower end surface of the intermediate plate, an upper surface of the elastic film, and an inner peripheral surface of the rigid ring; and an incompressible fluid sealed in the space section, and rubs and polishes a front, surface of a wafer with a polishing pad attached to an upper side of a turntable while holding a back surface of the wafer on a lower surface portion of the elastic film, the method including, before coupling the intermediate plate with the upper end surface of the rigid ring: forming, in the intermediate plate, an inlet through which the incompressible fluid is poured into the space section and an outlet through which air is discharged from the space section at the time of pouring the incompressible fluid; and forming, on a lower end surface of the intermediate plate, a groove which extends from the inlet to an outer peripheral portion of the intermediate plate and a groove which extends from the outlet to the outer peripheral portion of the intermediate plate, the method including, after attaching the elastic film to the lower: end surface of the rigid ring and coupling the upper end surface of the rigid ring with the lower end surface of the intermediate plate having the grooves formed thereon to form the space section: depressurizing the inside of the space section; and discharging the air in the space section from the outlet while pouring the incompressible fluid into the space section from the inlet after the depressurizing, and closing the inlet and outlet to seal the incompressible fluid in the space section.
In this manner, when such grooves as described above are formed on the surface of the intermediate plate on the space section side in advance and the incompressible fluid is sealed in, a flow of the incompressible fluid can be appropriately controlled at the time of pouring the incompressible fluid. That is, before the incompressible fluid closes the outlet, the air remaining in the space section can be discharged. Moreover, according to such a manufacturing method, the workability is good, and an amount of the incompressible fluid to be poured can be easily controlled.
At this time, in sealing the incompressible fluid in the space section, it is preferable to pour the incompressible fluid into the space section while mounting the intermediate plate at a slant so that the inlet is placed below the outlet.
With this arrangement, an amount of the air remaining in the space section can be further reduced.
Additionally, at this time, it is preferable to use, as the intermediate plate, a member whose lower end surface on which the grooves are formed has a convex shape.
With this arrangement, an amount of the air remaining in the space section can be further assuredly reduced.
Further, to achieve the object, the present invention provides a polishing head including: am annular rigid ring; an elastic film attached to a lower end surface of the rigid ring by uniform tensile force; a discoid intermediate plate coupled with an upper end surface of the rigid ring; a space section partitioned by the lower end surface of the intermediate plate, an upper surface of the elastic film, and an inner peripheral surface of the rigid ring; and an incompressible fluid sealed in the space section, and rubs and polishes a front surface of a wafer with a polishing pad attached to an upper side of a turntable while holding a back surface of the wafer on a lower-surface portion of the elastic film, the polishing head being characterized in that the intermediate plate includes, on the lower end surface thereof: an inlet through which the incompressible fluid is poured into the space section; an outlet through which air is discharged from the space section; a groove which extends from the inlet, to an outer peripheral portion of the intermediate plate; a groove which extends from the outlet to the outer peripheral portion of the intermediate plate; and lid sections which close the inlet and the outlet.
In such a polishing head, an amount of the air remaining in the space section having the incompressible fluid sealed therein is small, the shape of the surface of the elastic film on which the wafer is held can be easily controlled, and hence the wafer with high flatness can be manufactured with good reproducibility.
Furthermore, to achieve the object, the present invention provides a polishing apparatus including: a polishing pad attached to an upper side of a turntable; a polishing agent supply mechanism configured to supply a polishing agent onto the polishing pad; and the polishing head, the polishing apparatus being characterized in that a workpiece is held by the polishing head, and a front surface of the workpiece is rubbed and polished with the polishing pad attached to the upper side of the turntable.
The polishing apparatus including the polishing head, can manufacture the wafer having high flatness with the good reproducibility.
According to the method for manufacturing a polishing head of the present invention, an amount of the air remaining in the space section at the time of sealing in the incompressible fluid can be greatly reduced. Furthermore, this manufacturing method provides the excellent workability, and facilitates controlling an amount of the incompressible fluid to be sealed in.
Moreover, according to the polishing head of the present invention, an amount of the air remaining in the space section having the incompressible fluid sealed therein is small, the shape of the surface of the elastic film on which the wafer is held can be readily controlled, and hence the wafer having high flatness can be manufactured with good reproducibility. Additionally, the polishing apparatus including such a polishing head of the present invention can provide the same effect.
Although an embodiment according to the present invention will now be described hereinafter, the present invention is not restricted thereto.
As described above, the depressurizing and sealing method provides excellent workability and facilitates control over an amount of an incompressible fluid to be sealed in. However, the incompressible fluid which has been poured on an early stage before discharging a sufficient amount of air closes an outlet and enters, so to call, a state where an inlet and the outlet are short-circuited through the incompressible fluid, and hence there arises a problem that a large amount of air remains in a space section. On the other hand, the present inventors and others have discovered that an amount of remaining air can be reduced by forming grooves on a surface of an intermediate plate which partitions the space section to control a flow of the incompressible fluid in the space section, particularly control the incompressible fluid so that it first flows through an outer peripheral portion of the space section, thereby bringing the present invention to completion.
First, a polishing head according to the present invention will be described with reference to
Additionally, as shown in
Such a polishing head 1 can rub and polish a front surface of wafer with a polishing pad attached to a turntable while, holding a back surface of the wafer on the lower surface portion of the elastic film 3. Further, the polishing head 1 may have a backing pad attached to the lower surface portion of the elastic film 3, and the elastic film 3 may hold the wafer through this backing pad. The backing pad mentioned here is, e.g., a member which is soaked with water and attached to the wafer so that the wafer is held on a wafer holding surface of the elastic film 3. Furthermore, the polishing head 1 may include an annular template which holds an edge portion of the wafer on a lower surface of the backing pad.
In such a polishing head 1, since an amount of air remaining in the space section 5 is very small, a shape of the surface of the elastic film on which the wafer is held can be easily controlled at the time of polishing the wafer. Consequently, the polishing head which can manufacture the wafer having high flatness with excellent reproducibility can be provided.
Subsequently, a method for manufacturing a polishing head according to the present invention which enables manufacturing such a polishing head of the present invention as shown in
As shown in
First, before coupling the intermediate plate 4 with the upper end surface of the rigid ring 2, formation of such an inlet 7 and outlet 8 as shown in
Subsequently, on the lower end surface 4a of the intermediate plate 4, such grooves 10a and 10b as shown in
After forming the inlet 7, the outlet 8, and the grooves 10a and 10b in the intermediate plate 4 as described above, the elastic film 3 is attached to the lower end surface of the rigid ring 2 and the upper end surface of the rigid ring 2 is coupled with the lower end surface 4a of the intermediate plate 4 having the grooves formed, thereon as shown in
Subsequently, the inside of the space section 5 is depressurized (S104 in
Then, the incompressible fluid 6 is poured from the inlet 7 while keeping the outlet 8 open. As the incompressible fluid 6, using water is preferable in terms of safety and convenience. Moreover, it is preferable to set an inlet velocity to approximately 700 ml/min to 900 ml/min.
In a state where the central portion of the lower end surface 4a of the intermediate plate 4 is appressed against the elastic film 3 in this manner, when the incompressible fluid 6 is poured into the space section 5, the incompressible fluid 6 moves in the space section 5 as shown in
At this time, as shown in
Then, the incompressible fluid 6 flows along the outer peripheral portion 4b of the intermediate plate 4 and fills the outer peripheral portion of the space section 5 (an upper right part in
Here, in the present invention, it is preferable to use, as the intermediate plate 4, a member having a convex shape as the shape of the lower end surface 4a. When the intermediate plate 4 having such a shape is used, the incompressible fluid 6 is further apt to flow along the outer peripheral portion 4b of the intermediate plate 4. That is, a flow of the incompressible fluid 6 in the space section 5 can be easily controlled.
Subsequently, the incompressible fluid 6 reaches the outlet 8 through the groove 10b (a lower left part in
When the polishing head is manufactured based on such a procedure as described above, an amount of the air remaining in the space section 5 having the incompressible fluid 6 sealed in can be greatly reduced. Thus, it is possible to assuredly manufacture the polishing head according to the present invention which facilitates controlling the shape of the surface of the elastic film on which the wafer is held and enables manufacturing the wafer having high flatness with excellent reproducibility.
Further, the polishing head 1 according to the present invention manufactured in this manner can be used for holding a wafer W by, e.g., such a polishing apparatus 20 of the present invention as shown in
Furthermore, a surface of the workpiece W is rubbed and polished by a rotation movement of the polishing head 1 coupled with a rotary shaft and a turning movement of the turntable 23 while supplying a polishing agent 25 to the upper side of the polishing pad 22 by the polishing agent supply mechanism 24. According to such a polishing apparatus 20, a wafer having high flatness can be manufactured with excellent reproducibility.
Although the present invention will now be more specifically described hereinafter with reference to an example and comparative examples of the present invention, the present invention is not restricted thereto.
A polishing head was manufactured by the method, for manufacturing a polishing head according to the present, invention based, on a flow shown in
A polishing head was assembled in the water which is the incompressible fluid to fabricate the polishing head having the water sealed in the space section. The polishing head fabricated in Comparative Example 1 has a basic structure equal to that of the polishing head in Example 1, but it does not have grooves, an inlet, an outlet, and a lid sections on a lower end surface of an intermediate plate.
A polishing head was basically manufactured in the same manner as Example 1 except that a groove extending from an inlet to an outer peripheral portion of an intermediate plate and a groove extending from an outlet to the outer peripheral portion of the intermediate plate were not formed and water was sealed in a space section by a conventional depressurizing and sealing method.
Workability, an air residual amount, and sealing amount controllability in each of Example and Comparative Examples 1 and 2 were evaluated.
Here, the workability was evaluated in terms of a polishing head assembly operation time, a time of five minutes or less was evaluated as “good”, and a time of five minutes or more was evaluated as “poor”. As shown in Table 1, in each Example 1 and Comparative Example 2 using the depressurizing and sealing method, since the work can be performed in a state where the polishing head, is assembled in air, an operation time was reduced as compared with a method for assembling the head in the incompressible fluid. It is to be noted that an operation time in Example is a time which is ⅓ or less of that of Comparative Example 2.
The air residual amount was converted into an area, an amount which is 3% or less of the space section was evaluated as “good”, and an amount which is 3% or more was evaluated as “poor”. Consequently, in Comparative Example 1 adopting an underwater assembling system, the remaining air was 0% when it was converted into an area, and hence it was evaluated as “good”. Further, in the polishing head manufactured by the present invention, the remaining air was slightly observed, but it was approximately 1% when it was converted into an area, and hence it was evaluated as “good”. It is to be noted that this is an air residual amount which does not adversely affect polishing of a wafer. On the other hand, in the polishing head of Comparative Example 2, since the remaining air was 20% when it was converted into an area, it was evaluated as “poor”.
In the underwater assembling system in Comparative Example 1, the sealing amount controllability was evaluated as “poor” since a sealing amount of the water was not successfully adjusted. On the other hand, in the depressurizing and pouring method like Example, since a sealing amount of water can be controlled by an amount of the incompressible fluid to be supplied, and hence the controllability was evaluated as “good”. In case of the polishing head of Comparative Example 2, even if a sealing amount of water can be controlled, a desired amount of the incompressible fluid cannot be sealed in due to an influence of the remaining air, and a shape of a wafer holding section of the polishing head cannot be actually fixed. Thus, it was evaluated as “substantially poor”.
Moreover, the polishing head manufactured in each of Example and Comparative Example 1 was used as a polishing head of such a single-side polishing apparatus as shown in
A silicon single crystal wafer was polished under these conditions, and its flatness was evaluated. Table 2 shows the results. For the evaluation of the flatness, an average value of outer periphery stock removal variations was used. The outer periphery stock removal variation mentioned here represents a difference between stock removals at points which are 1 mm and 3 mm apart from the outer periphery toward the center respectively and, when this value is lowered, it means that even the outer peripheral portion is flatly polished. It is to be noted that, in Comparative Example 2, since an air residual volume is large, the wafer could not be properly handled when the same sealing amount as that in Example or Comparative Example 1 was set, and hence data of the outer periphery stock removal variation was not provided.
It is to be noted that the present invention is not restricted to the embodiment. The embodiment is an illustrative example, and any example which has substantially the same configuration and exerts the same functions and effects as the technical concept described in claims of the present invention is included in the technical scope of the present invention.
Number | Date | Country | Kind |
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2015-084098 | Apr 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/001148 | 3/3/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/166928 | 10/20/2016 | WO | A |
Number | Name | Date | Kind |
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4897966 | Takahashi | Feb 1990 | A |
9266216 | Masumura | Feb 2016 | B2 |
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20140113531 | Masumura | Apr 2014 | A1 |
20150017890 | Masumura | Jan 2015 | A1 |
Number | Date | Country |
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S63-52967 | Mar 1988 | JP |
2013-166200 | Aug 2013 | JP |
2013001719 | Jan 2013 | WO |
Entry |
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Apr. 26, 2016 Search Report issued in International Patent Application No. PCT/JP2016/001148. |
Number | Date | Country | |
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20180043500 A1 | Feb 2018 | US |