KR20140125289A - Carrier head of chemical mechanical apparatus and membrane used therein - Google Patents

Abstract

The present invention relates to a carrier head in a chemical mechanical polishing apparatus and a membrane used therein. The carrier head comprises: a main body; a base which rotates with the main body; a retainer ring which has a ring shape covering around the base, and rotates with the main body by being installed to be supported by one among the main body or the base; and a membrane. The membrane has: a bottom plate whose bottom comes into contact with a surface of a wafer during a chemical mechanical polishing process; and a side formed by bending at the radial end of the base plate. A pressurizing chamber is formed at the upper part of the side by forming a first fixing flip fixed to the retainer ring and a second fixing flip fixed to the base on the side by extending. Also, the membrane forms pressure chambers in a space made between the base and the membrane. As a result of placing the pressurizing chamber at the upper part of the side of the membrane, the entire force introduced by adjusting the pressure of the pressurizing chamber can be used as a vertical pressing force pressurizing an edge of a wafer, thereby applying the accurate vertical pressing force to an edge of a wafer.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a carrier head of a chemical mechanical polishing apparatus and a membrane used therefor. BACKGROUND OF THE INVENTION [0002]

The present invention relates to a carrier head of a chemical mechanical polishing apparatus and a membrane used therefor, and more particularly to a carrier head of a chemical mechanical polishing apparatus capable of accurately pressing a periphery of a wafer while applying a small air pressure during a chemical mechanical polishing process, To a membrane used therefor.

The chemical mechanical polishing (CMP) apparatus is a device for performing a wide-area planarization that removes a height difference between a cell region and a peripheral circuit region due to unevenness of a wafer surface generated by repeatedly performing masking, etching, To improve the surface roughness of the wafer due to contact / wiring film separation and highly integrated elements, and the like.

In such a CMP apparatus, the carrier head presses the wafer in a state in which the polished surface of the wafer faces the polishing pad before and after the polishing step to perform the polishing process, and at the same time, when the polishing process is finished, the wafer is directly or indirectly Vacuum-adsorbed and held, and then moved to the next step.

Fig. 1 is a schematic view of the carrier head 1. Fig. 1, the carrier head 1 includes a body 110, a base 120 that rotates with the body 110, and a ring 120 surrounding the base 120, An elastic membrane 140 which is fixed to the base 120 and forms pressure chambers C1, C2, C3, C4, and C5 in a space between the base 120 and the base 120; And a pressure control unit 150 for controlling the pressure by introducing air into or out of the pressure chambers C1, C2, C3, C4, and C5 through the pneumatic supply path 155.

The elastic membrane 140 is formed by bending the side surface 142 at the edge of the flat bottom plate 141 pressing the wafer W. A central end 140a of the membrane 140 is fixed to the base 120 to form a suction hole 77 for sucking the wafer W directly. It may be formed as a surface that pressurizes the wafer W without forming a suction hole at the center of the membrane 150. A plurality of ring-shaped partition walls 143 fixed to the base 120 are formed between the center of the membrane 140 and the side surface 142 to define a plurality of pressure chambers C1, C2, C3 , C4, and C5 are arranged in concentric circles.

A side pressure chamber Cx surrounded by a fixed flip extending from the side surface 142 is formed on the side surface 142 of the membrane 140. [ The pneumatic pressure of the pressure chamber Cx is also controlled by the pressure control unit 150 so that when the pneumatic pressure is supplied to the pressurizing chamber Cx, as shown in Figs. 2 and 9, the inclined surface Cs of the pressurizing chamber Cx The force Fcx is inclined to the inclined face of the annular ring 160 and the force component Fv in the vertical direction among the force Fcx transmitted to the annular ring 160 is transmitted through the side face 142 to the wafer W).

Thus, only the vertical component of the inclination angle r1 of the inclined plane Cs in the force Fcx that presses the inclined plane Cs by the pressure introduced into the pressurizing chamber Cx is transmitted to the side face 142 of the membrane 140, The pressure introduced into the pressurizing chamber Cx must be excessively increased in order to transmit the vertical pressing force Fv of a desired size to the edge of the wafer through the side surface 142 . Not only this but also the horizontal component of the inclination angle r1 of the inclined plane Cs in the force Fcx that presses the inclined plane Cs by the pressure introduced into the pressurizing chamber Cx is larger than the horizontal component of the side face 142 of the membrane 140, Which causes the edge of the membrane bottom plate to float. Reference numeral 145 denotes a mounting projection for positioning the annular ring 160 on the side surface 142.

At the same time, pneumatic pressure is transmitted from the pressure control unit 150 to the pressure chambers C1, C2, C3, C4, and C5 via the pneumatic supply path 155, The plate surface of the wafer W located on the bottom surface of the bottom plate 141 is pressed by the pressures (... P4, P5).

However, in order to press the edge of the wafer W, the carrier head 1 of the chemical mechanical polishing apparatus configured as described above supplies pneumatic pressure from the pressure control unit 150 to the pressurizing chamber CX, The inclined face Cs is pressed by the pressure of the pressurizing chamber CX and the horizontal component of the force Fcx pressed against the inclined face Cs is not used and the vertical component is applied to the membrane 140. [ Is transmitted to the wafer W by the vertical pressing force Fv through the side surface 142 of the wafer W.

When the inclined face Cs of the pressurizing chamber CX is 45 degrees, only 1/2 of the force Fcx pressed by the pressurizing chamber CX is used as the vertical pressing force Fv, Not only the inefficiency of supplying excessively high pneumatic pressure to the chamber Cx through the pneumatic supply passage 155X but also the ineffectiveness of the pressure chambers Cx A pressure difference between the pressure chambers C1, C2, C3, C4, and C5 and the pressure chamber Cx is large, It becomes difficult to accurately control the pressure of the exhaust gas.

Not only this but also a force of approximately one-half of the horizontal component which is not used as the vertical pressing force Fv pushes the side surface 142 of the membrane 140 outward in the radial direction, A problem arises that an accurate force can not press the edge of the wafer W in spite of the inner pressure P5 in the outer radius of the outer chamber C5.

SUMMARY OF THE INVENTION The present invention has been made in view of the above technical background and it is an object of the present invention to provide a carrier head of a chemical mechanical polishing apparatus capable of precisely pressing the edge region of a wafer during a chemical mechanical polishing process and a structure of a membrane used therefor do.

Another object of the present invention is to accurately apply the vertical pressing force intended to the edge of the wafer through the side surface of the membrane without increasing the capacity of the pressure control unit for supplying pneumatic pressure to the pressure chamber.

That is, according to the present invention, a pressure chamber is formed above the side surface of the membrane, and even when the pressure applied to the pressure chamber is kept small, a large load can be reliably provided in proportion to the pressure applied to the large area of the bottom surface of the pressure chamber. So that it can be applied to the edge of the wafer edge.

It is therefore an object of the present invention to reliably manufacture a semiconductor package even at the edge of a wafer as uniform polishing is performed on the edge of the wafer.

Further, according to the present invention, since the width (x2) of the pressure chamber located at the outermost position of the chamber used to press the wafer is larger than the pressure chamber in which the pressure chamber is located, the vertical pressing force applied through the side So that the edges of the wafer can be reliably planarized.

In the present invention, abrasive particles, slurry, or the like is introduced into the interior of the carrier head during the chemical mechanical polishing process by blocking the membrane side and the retainer ring by connecting them with the first fixed flip extending from the upper side of the membrane side And the like.

According to an aspect of the present invention, A base rotatably driven with the main body; A retainer ring which is formed in a ring shape surrounding the periphery of the base and rotatably driven together with the main body, the retainer ring being installed to be supported by the main body and the base; A base plate having a bottom surface in contact with the plate surface of the wafer during a chemical mechanical polishing process and a side surface formed by bending at a radial end of the bottom plate and having a first fixed flip fixed to the retainer ring, And a second fixed flip fixed to one of the main bodies extends to form a pressure chamber above the side surface and forms a pressure chamber in a space between the base and the base; The present invention also provides a carrier head for a chemical mechanical polishing apparatus.

This is because the side surface of the membrane for pressing the wafer is fixed to the retainer ring and the base through the first fixed flip and the second fixed flip, respectively, so that the pressure chamber, which applies the vertical pressing force to the edge of the wafer through the side surface of the membrane, As shown in FIG. As a result, unlike the conventional case where the pressurizing chamber is located inside the side surface of the membrane and only a part of the force introduced by the pressure of the pressurizing chamber acts as the vertical pressing force by the inclined surface, the pressurizing chamber is located on the upper side of the membrane, It becomes possible to apply all of the force introduced by the pressure with the vertical pressing force.

Particularly, since the force corresponding to the product of the area of the bottom surface of the pressurizing chamber located on the upper side of the membrane and the pressure applied to the pressurizing chamber is transmitted downward through the side surface by the vertical pressing force, even if the pressure applied to the pressurizing chamber is small It is possible to obtain an advantageous effect that the vertical pressing force can be stably and reliably applied to the edge of the wafer.

The upper surface of the membrane is formed as a horizontal upper surface so that the horizontal upper surface is the bottom surface of the pressure chamber so that the force corresponding to the product of the air pressure supplied to the pressure chamber and the bottom surface width To be applied to the edge of the wafer, so that an accurate vertical pressing force can be introduced through the side of the membrane at the edge of the wafer during the chemical mechanical polishing process. Thus, according to the present invention, the semiconductor package can be reliably manufactured even at the edge of the wafer as the wafer is uniformly polished against the edge.

In addition, since the ends of the first fixed flip and the second fixed flip that form the pressurizing chamber are fixed to the retainer ring and the base and the body, respectively, as described above, the gap between the side surface of the membrane and the retainer ring It is possible to prevent foreign matter such as abrasive grains and slurry from flowing into the inside of the carrier head through the gap between the side surface of the membrane and the retainer ring during the chemical mechanical polishing process. Accordingly, even when the carrier head is used for a long time, foreign matter such as slurry does not flow into the inside of the carrier head, so that a reliable performance can be assured for a long period of time.

At this time, the first fixed flip and the second fixed flip start to extend horizontally at the upper portion of the membrane side, so that the upper surface of the membrane side is formed as a flat horizontal surface. Thereby, the force in accordance with the pressure of the pressurizing chamber is directly transmitted to the edge of the wafer along the side of the membrane through the flat horizontal surface forming the bottom surface of the pressurizing chamber.

Wherein the side has a third fixed flip extending outwardly from the middle of the second fixed flip to position the pressure chamber above the side of the membrane and wherein the end of the second fixed flip and the end of the third fixed flip Wherein an end of the third fixed flip is fixed at a position higher than an end of the second fixed flip and a pressure chamber for pressing the side is fixed to the first fixed flip and the third fixed flip, As shown in Fig.

At this time, a fitting ring is provided in the retainer ring between a position where the end of the first fixed flip is fixed and a position where the end of the third fixed flip is fixed, and the end ring of the first fixed flip It is much easier to install the end of the fixed flip.

A ring-shaped ring of a flexible elastic material having an outer end fixed to the retainer ring and an inner end fixed to the base is provided on the upper side of the side surface of the membrane . Thereby, a space surrounded by the chamber ring, the side surface of the membrane, the inner circumferential surface of the retainer ring, and the outer circumferential surface of the base is formed as a pressurizing chamber. By arranging the chamber ring of the flexible elastic material at a position spaced upward from the membrane side so as to position the upper portion of the membrane side in the central portion with respect to the end face of the pressurizing chamber so that the volume of the pressurizing chamber is sufficiently large, The side surface can be reliably pressed downward perpendicularly.

At this time, a fitting ring is provided in the retainer ring between a position where the end of the first fixed flip is fixed and a position where the outer end of the chamber ring is fixed, and the end ring of the first fixing flip and the chamber ring It is possible to make it much easier to install the outer end of the housing.

In order to reduce the inconvenience that the pressurizing chamber is directly placed on the upper side of the membrane as described above and the chamber ring needs to be separately provided at the upper side spaced apart from the side of the membrane, the end of the first fixed flip is fixed to the retainer ring Wherein a ring-shaped fitting block of a flexible elastic material is formed on the ring-shaped fitting block, and the ring-shaped fitting block is formed with a chamber flip extending inward from a position spaced upward from a connection portion with the first fixed flip, And the base, and a pressure chamber may be formed on the lower side of the chamber flip.

In other words, the ring-shaped fitting block corresponds to the fitting ring of the above-described another embodiment, and the chamber flip corresponds to the chamber ring of the above-described other embodiment, but the ring-shaped fitting block and the chamber flip are integrally formed with the membrane So that it is easy to manage the parts. Further, since the ring-shaped fitting block is inserted and fixed in the retainer ring at the end of the first fixed flip, the effect of fixing the first fixed flip to the retainer ring becomes more complete, so that the state in which the pressure chamber is formed can be maintained more stably It is possible to more effectively prevent the foreign matter flowing into the interior of the carrier head through the gap between the retainer ring and the membrane side.

On the other hand, in the membrane bottom plate which presses the plate surface of the wafer, a ring-shaped partition wall extends upward and is fixed to the base, so that a plurality of pressure chambers are formed between the membrane and the base. At this time, in order to control the vertical pressing force applied to the edge of the wafer through the side surface even if the pressure supplied to the variously configured pressure chambers is lowered, the width in the radial direction of the pressing chamber located on the side surface is large The width of the outermost pressure chamber located on the outermost side of the pressure chamber of the first pressure chamber.

A reinforcing material having a higher hardness than the hardness of the bottom surface of the membrane may be integrally formed on the side surface of the membrane. As a result, even if the pressure of the outermost pressure chamber is increased, the side of the membrane bulges outwardly convexly to minimize the floating of the edge of the bottom edge of the membrane. Further, since the reinforcing material is integrally formed on the side surface of the membrane, the membrane is hardly deformed by the stiffener even if it is used for a long period of time, so that the edge area of the wafer is not lifted for a long time and uniform pressure is introduced into the edge of the wafer The effect can be obtained.

According to another aspect of the present invention, there is provided a membrane of a carrier head for a chemical mechanical polishing apparatus, comprising: a bottom plate formed of a flexible elastic material and pressing a surface of a wafer; a base plate formed of a flexible elastic material, And the upper side is provided with a first fixed flip extending toward the inside and a second fixed flip extending toward the outside; And a carrier head for a chemical mechanical polishing apparatus.

At this time, it is preferable that the first fixed flip and the second fixed flip start to extend in the horizontal direction, and the upper part of the side is formed as a flat horizontal plane.

The membrane side has a third fixed flip extending outward from the middle of the second fixed flip so that a pressure chamber is formed in a space between the first fixed flip and the third fixed flip, It is possible to directly place the pressure chamber in the pressure chamber.

The first fixed flip and the third fixed flip are fixed to a retainer ring surrounding the outer side of the carrier head so that a pressure chamber for pressing along the side is formed between the first fixed flip and the third fixed flip.

According to another embodiment of the present invention, a ring-shaped fitting block of a flexible elastic material fixed to the retainer ring of the carrier head is formed at an end of the first fixed flip. As a result, the ring-shaped fitting block having a relatively large volume and weight is fixed to the retainer ring, so that the thin first fixed flip can be more stably fixed to the retainer ring as compared with the ring-shaped fitting block.

At this time, the ring-shaped fitting block is formed with a chamber flip extending inward from a position spaced upward from the connecting portion of the first fixed flip. Thereby, the end of the chamber flip is fixed to either the base or the body, so that a region surrounded by the chamber flip, the ring-shaped fitting block, the first fixed flip, and the like is formed as the pressurizing chamber.

And a ring-shaped stiffener having a higher hardness than the bottom plate is integrally formed on the side surface of the membrane. Thus, even when the pressure of the outermost pressure chamber is increased, the side surface of the membrane expands outward convexly, minimizing the floating of the edge of the bottom edge of the membrane, so that a uniform pressure can be introduced into the edge of the wafer .

The term " extend outwardly "or" extend inward "and the like described in this specification and claims means extending in the outward direction or inward direction, "And " Therefore, the meaning of "extending horizontally outwardly " in the present specification and claims is not only extended horizontally in the outward direction, but also extends horizontally in the outward direction and forms a bent portion in the middle .

According to the present invention, the first fixed flip and the second fixed flip extending respectively to the membrane side upper end portions of the carrier head are respectively fixed to the retainer ring and the base, and the pressurizing chamber is located above the side surface of the membrane, A large vertical pressing force proportional to the area of the bottom surface of the pressurizing chamber can be applied to the edge of the wafer through the side surface so that an advantageous effect of reliably flattening the edge of the wafer can be obtained.

Further, the present invention is characterized in that the radial width of the pressurizing chamber formed on the side of the membrane is formed larger than the outermost pressure chamber among the plurality of divided pressure chambers, so that the magnitude of the vertical pressing force introduced into the edge of the wafer It becomes possible to largely control.

In addition, the present invention can form a pressurizing chamber having a horizontal bottom surface at the upper side of the membrane side, so that all of the force introduced through the pressure control of the pressurizing chamber can be used as a vertical pressing force for pressing the edge of the wafer An advantageous effect that an accurate vertical pressing force can be introduced to the edge of the wafer can be obtained.

Thus, according to the present invention, the semiconductor package can be reliably manufactured even from the edge of the wafer as the uniform polishing is performed on the edge of the wafer.

In addition, the present invention is characterized in that the ends of the first fixed flip and the second fixed flip that form the pressurizing chamber are fixed to either the retainer ring and the base and the body respectively, thereby preventing the gap between the side of the membrane and the retainer ring It is possible to prevent foreign substances such as abrasive grains and slurry from flowing into the inside of the carrier head through the gap between the side surface of the membrane and the retainer ring during the chemical mechanical polishing process so as to ensure the reliable performance of the carrier head for a long period of time You can get an advantage.

Further, since the present invention uses all of the force due to the pressure introduced into the pressurizing chamber as a vertical pressing force for pressing the edge of the wafer, the pressure is introduced into the pressure chamber which presses the surface of the wafer and the pressure value introduced into the pressurizing chamber The deviation of the pressure value becomes small, so that the capacity of the pressure control unit for supplying the air pressure to these chambers can be reduced as compared with the conventional one, and the control accuracy of the pneumatic pressure is also improved.

1 is a half sectional view showing the structure of a conventional carrier head,
Fig. 2 is an enlarged view of a portion 'A' in Fig. 1 for explaining the principle of pressing a wafer edge,
3 is a half sectional view showing a membrane of a carrier head according to a first embodiment of the present invention,
FIG. 4 is an enlarged view of an edge portion of the carrier head according to the first embodiment of the present invention with the membrane of FIG. 3;
FIG. 5 is a schematic view illustrating a portion 'B' in FIG. 4, illustrating a principle of transmitting a vertical pressing force by a pressure of a pressurizing chamber,
6 is an enlarged view of an edge portion of a carrier head according to a second embodiment of the present invention in which a membrane according to a second embodiment of the present invention is provided;
7 is a half sectional view showing a membrane of a carrier head according to a third embodiment of the present invention,
FIG. 8 is an enlarged view of an edge portion of the carrier head according to the third embodiment of the present invention in which the membrane of FIG. 7 is provided;
Fig. 9 is a view for explaining the principle of transmitting the vertical pressing force of the conventional carrier head of Fig. 2;

The membrane 340 used in the carrier head for the chemical mechanical polishing apparatus according to the first embodiment of the present invention has a structure as shown in the half sectional view of Fig. (The carrier head 2, 2 ', 3 and the membranes 240, 240', 340 according to the present invention are in a shape rotated about the center line 88 of the half-sectional view shown in the figure.)

The carrier head 3 according to the first embodiment of the present invention includes a main body coupled to a driving shaft (not shown) to be rotationally driven, a base 320 connected to the main body and rotated together, A ring-shaped retainer ring 330 which is fixed to one of them and rotates together and a ring-shaped retainer ring 330 which is fixed to the base 120 and forms pressure chambers (..., C4, C5) between the base 120 and the elastic flexible material And a pressure control unit 250 for controlling the pressure by supplying pneumatic pressure to the pressure chambers C4 and C5.

The membrane 340 according to the first embodiment of the present invention includes a bottom plate 341, side surfaces 342 bent upward from the edge of the bottom plate 341 and extending upward, A plurality of ring-shaped partition walls 343 and 343 'are formed which are coupled to the base 320 between the center of the base plate 320 and the side surface 342. [ C4 and C5 are formed between the base 330 and the membrane 340 as a plurality of ring-shaped partition walls 343 and 343 'are formed.

Meanwhile, the central portion 340a of the membrane 340 is coupled to the base 320, and the suction hole (77 in FIG. 1) for directly sucking the wafer W is provided at the center portion. However, according to another embodiment of the present invention And the central portion of the membrane 340 is clogged with a bottom plate 341. [

As shown in Figures 3 and 4, fixed flips 3421, 3422, 3433 extend from the side 342 at the top of the membrane side 342. 4, the first fixed flip 3421 has an end fixed to the retainer ring 330, the second fixed flip 3422 has an end fixed to the base 320, and a third fixed The flip 3423 is fixed to the retainer ring 330 at a position where the end is higher than the position where the end of the first fixed flip 3421 is fixed.

To this end, the retainer ring 330 is provided with a fitting ring 335 inserted into the recessed groove so as to fix the ends of the first fixed flip 3421 and the third fixed flip 3423 at different heights, respectively . The fitting ring 335 may be formed of a flexible elastic material or a plastic or metal material. The base 320 includes fixing anchors 3221 and 3222 which are sequentially coupled to fix the end of the partition walls 343 and 343 'of the membrane 340 and the second fixed flip 3422, respectively .

The pressing chamber Cx for pressing the edge of the wafer W is formed as a region surrounded by the first fixed flip 3421 and the third fixed flip 3423 and the fitting ring 335, 342, respectively. At this time, the pressure chambers Cx are formed by the first fixed flip 3421 to cover the upper side of the gap CL between the retainer ring 330 and the membrane flip 342, so that during the chemical mechanical polishing process, It is possible to prevent the slurry or abrasive particles remaining on the carrier head 3 from flowing into the interior of the carrier head 3 through the gap CL and to reliably use the carrier head for a long time without contamination of the carrier head.

The first fixed flip 3421 extending from the upper end of the membrane side surface 342 starts to extend in the horizontal direction of the outer side and is provided with a bent portion for fixing the end to the retainer ring 330, 3422 extend in the horizontal direction inside. Thus, as the first fixed flip 3421 and the second fixed flip 3422 are configured to begin to extend in different horizontal directions from the top of the membrane side 342, the membrane side 342 has a flat horizontal surface 342s And this flat horizontal surface 342s serves as an intermediate passage for transmitting the pressing force Fcx of the pressurizing chamber Cx. The force Fcx generated from the pressurizing chamber Cx is transmitted to the pressure chamber Cx through the pneumatic supply part 255x from the pressure control part 250 so that the direction of the force Fcx generated from the pressurizing chamber Cx is equal to All of the force Fcx transmitted by the bottom surface of the pressurizing chamber Cx can be used as the vertical pressing force Fv for pressing the edge of the wafer W. [

5, when the pressure Pi is supplied to the pressurizing chamber Cx through the pneumatic supply part 255x, the force Fcx pushing the bottom surface is equal to the pressure Pi applied to the bottom surface The first fixed flip 3421 and the second fixed flip 3422 extend inwardly and outwardly and are fixed to the main body, the base and the retainer ring 330, respectively, and are fixed to the bottom of the pressurizing chamber Cx The vertical pressing force Fv transmitted through the membrane side surface 342 can be largely affected even if the pressure Pi supplied to the pressurizing chamber Cx is small because the width x2 of the surface is extremely large in the radial direction.

For example, the bottom surface width x2 of the pressurizing chamber Cx is set such that the width in the radial direction of the outermost pressure chamber C5 of the pressure chambers C1, C2, ..., C5 divided by the partition wall (X5). That is, the pressure chamber Cx located at the outermost of the plurality of chambers C1, C2, ..., C5, Cx to which the air pressure is supplied has a radius of the outermost pressure chamber C5 The width X2 may be larger than the width X5 of the direction. As a result, the width X2 of the pressurizing chamber Cx is formed to be larger than the vertical pressing force pressing the edge of the wafer through the membrane side surface 342 even if the pressure Pi applied to the pressurizing chamber Cx is not large. Fv) can be largely transmitted and actuated.

Even if a pressure equal to or similar in magnitude to the pneumatic pressure supplied to the pressure chambers C1, C2, ..., C5 divided into the plurality of pressure chambers Cx is applied to the pressure chambers Cx, It is possible to apply the vertical pressing force Fv largely, so that it is possible to surely press the edge of the wafer with a large force.

Accordingly, it is possible to solve the problem of introducing excessive pressure into the pressurizing chamber as the vertical pressing force Fv is transmitted to the wafer W through the inclined surface in the related art (assuming that the inclined surface of the conventional pressurizing chamber is inclined at 45 degrees) Not only the edge of the wafer W can be pressed with a pressure of 1/2 of that of the conventional one but also the component force in the horizontal direction of the pressing force Fcx of the pressing chamber becomes zero, The tendency to be convex outwardly is further reduced, and the advantage that the edge edge of the membrane bottom plate 341 is lifted naturally is also obtained.

Therefore, the present invention can accurately introduce the vertical pressing force Fv to the edge of the wafer W and improve the polishing quality at the edge of the wafer W. Therefore, The package can be manufactured with reliability.

In addition, since all the force Fcx pushing downward by the pressure introduced into the pressurizing chamber Cx is used as the vertical pressing force Fv for pressing the edge of the wafer W, The pressure value introduced into the pressurizing chamber Cx through the pneumatic pressure supply path 255x from the pressure control unit 250 and the pressure value introduced into the pressurizing chamber Cx through the pneumatic pressure supply path 255x when compared with the conventional configuration (see Fig. 2) C4, and C5 from the pressure control unit 250 through the pneumatic supply path 2555 to press the plate surface of the chamber Cx, ..., C4, C5, The capacity of the pressure control unit 250 for supplying the pneumatic pressure to the first, second, third, fourth, fifth, sixth, seventh, eighth, eighth, ninth, tenth, fourth, fifth, sixth, seventh, eighth and ninth embodiments of the present invention.

On the other hand, on the membrane side surface 342, ring-like stiffeners 271, 272 having a higher hardness than the hardness of the membrane bottom plate 341 are integrally formed on the outer grooves 342x and the inner protrusions 342y. Thereby, the efficiency of transmitting the vertical pressing force Fv through the side surface 342 is improved. Even if the pressure P5 of the outermost pressure chamber C5 increases, the membrane side surface 342 expands outward convexly by the ring-shaped stiffeners 371 and 372 having higher hardness, and the membrane bottom plate 341 ' And it is possible to prevent deformation of the membrane due to the stiffeners 271 and 272 even if the membrane is used for a long period of time.

3, the bottom plate 341 of the membrane 340 includes a flat region F including a central portion and a flat bottom region, a membrane region 342 extending from an end in the radial direction of the flat region, And an inclined portion 347 inclined upward by a width of 4 mm to 10 mm such that the inclined portion 347 is inclined at an angle of about 0.5 to 5 degrees. The vertical pressing force Fv that presses the edge region of the wafer W is applied to the side surface 342 of the membrane W via the membrane side surface 342. As a result of the provision of the excited region E formed by the inclined portion 247 inclined upward in the radial outward direction, The edge of the bottom plate 341 is displaced downward by the inclined portion 347 of the excited region E so that the edge of the bottom plate is pushed inward in the horizontal direction, The edge portion of the wafer W can be accurately pressed by the pressure P5 of the outermost pressure chamber C5 while the slope portion 347 is expanded and brought into close contact with the surface of the wafer W .

The thickness of the bottom plate 241 'below the outermost pressure chamber C5 formed between the outermost ring-shaped partition wall 343' and the side surface 342 of the membrane 340 is larger than the thickness of the outermost ring-shaped partition wall 243 ' Of the thickness of the bottom plate 241 to the center of the bottom plate, and a ring-shaped groove 343a formed inside the outer base of the outermost ring-shaped partition wall 343 ' .

As described above, since the bottom plate 341 'of the outermost pressure chamber C5 is formed to be thin, the pressure P5 applied by the outermost pressure chamber C5 is more accurately transmitted to the edge region of the wafer W And the membrane bottom plate 341 'which is made thinner by the pressure P5 of the outermost pressure chamber C5 is easily expanded so as to be brought into close contact with the surface of the wafer during the CMP process so that the pressing force .

The outermost ring-shaped partition wall 343 'is provided with a ring-shaped groove 343a which is formed by being recessed inward at the outer side base portion of the outermost ring-shaped partition wall 343' When the pressure difference P4-P5 between the outermost pressure chamber C5 and the adjacent pressure chamber C4 is generated, the bottom plate between the pressure chambers C4 and C5 is swung The ring-shaped partition wall 243 'easily flows and changes the volumes of the pressure chambers C4 and C5 so that the pressure difference between the adjacent pressure chambers C4 and C5 causes the pressure difference between the bottom plate It is possible to further suppress the occurrence of wrinkles in the wings 341 '.

Hereinafter, the carrier head 2 of the chemical mechanical polishing apparatus according to the second embodiment of the present invention will be described in detail. It should be noted, however, that the same or similar components and functions as those of the above-described first embodiment are denoted by similar reference numerals, and a description thereof will be omitted for the sake of clarity of the second embodiment.

6, the carrier head 2 according to the second embodiment of the present invention is positioned above the side surface 242 of the membrane 240 by a chamber ring 260 spaced from the membrane side surface 242 Which is different from the first embodiment described above in that the pressurizing chamber Cx is formed in the pressure chamber Cx.

That is, a first fixed flip 2421 and a second fixed flip 2422 extend from the side surface 342 in the horizontal direction on the outer side and the inner side, respectively, on the upper side of the membrane side surface 242. The end of the first fixed flip 2421 is fixed to the retainer ring 230 and the end of the second fixed flip 2422 is fixed to either the base 220 or the main body. A chamber ring 260 is secured to the retainer ring 230 and an inner end 2602 is secured to the base 220 at an upwardly spaced location from the top of the membrane side surface 242 And a pressurizing chamber Cx is formed by a separate chamber ring 260 instead of the third fixed flip 2423. That is, a space surrounded by the side surface upper portion 343s of the membrane, the inner circumferential surface of the retainer ring 230, and the outer circumferential surface of the base 320 is formed as a pressurizing chamber Cx on the lower side of the chamber ring 260.

Since the upper portion of the membrane side surface 242 can be positioned at the center of the pressurizing chamber Cx by positioning the chamber ring 260 of flexible elastic material at a position spaced upward from the membrane side surface 342, Even if a displacement occurs in which the first fixed flip 2421, the second fixed flip 2422 and the chamber ring 260 which are flexible elastic materials surrounding the pressurizing chamber Cx are bent upward and downward, The upper surface 342s of the membrane side surface 242 maintains a flat horizontal surface so that the direction of the force Fcx pushing down the upper portion of the membrane side surface 242 by the pressurizing chamber Cx is always directed downward vertically You can get an advantage.

The first fixed flip 2421 and the second fixed flip 2422 are coupled to the main body or the base and the retainer ring 230 so that the bottom surface of the pressurizing chamber Cx Is formed to be large in the radial direction by the first fixed flip 2421 and the second fixed flip 2422. That is, as in the first embodiment, the width X2 of the bottom surface of the pressurizing chamber Cx is equal to the width X2 of the plurality of pressure chambers C1, C2, ..., C5 formed between the membrane and the base May be larger than the width X5 of the outer pressure chamber C5.

5, when the pressure Pi is supplied to the pressurizing chamber Cx through the pneumatic supply part 255x, a force multiplied by the bottom surface area of the pressurizing chamber Cx is applied to the supply pressure Pi, The pushing force Fcx pushes the bottom face downward and the sum of the pushing forces Fcx is transmitted through the side face 242 (including the stiffener 271) to press the edge of the wafer edge.

Further, since the upper side of the membrane side surface 242 is formed as the horizontal surface 242s, the pressure acting on the bottom surface width X2 of the pressurizing chamber Cx is all transmitted to the membrane side surface 242 without loss, The pressure control of the cylinder Cx can be more efficiently performed.

Since the bottom surface of the pressurizing chamber Cx is formed to be large in the radial direction by the first fixed flip 2421 and the second fixed flip 2422, the pneumatic pressure Pi introduced into the pressurizing chamber Cx The vertical pressing force Fv transmitted through the membrane side surface 242 can be increased.

The first position of the retainer ring 230 to which the end of the first fixed flip 2321 is fixed and the second position of the retainer ring 230 to which the outer end of the chamber ring 260 is fixed are provided with a flexible elastic material It is easier to fix the end of the first fixed flip 2421 and the outer end of the chamber ring 260 to the retainer ring 230 at different heights .

A second fixed flip 2422 extending inwardly from the membrane side 342 and an inner end 2602 of the chamber ring 260 and an outermost partition 243 ' The base 220 is provided with fixing anchors 2221, 2222, 2223 and 222 so that the base 220 can be sequentially fixed in position. This makes it easier to fix the second fixed flip 2422 and the inner edge 2602 of the chamber ring 260 and the outermost partition wall 243 'of the membrane 240 at different heights .

Reference numeral 2554 in the figure denotes a pneumatic pressure supply line for supplying pneumatic pressure to the pressure chamber C4, and P4, which is not described, is a pressing force for pressing the pressure chamber C4 from the pressure chamber C4 toward the wafer W.

The carrier head 2 according to the second embodiment of the present invention also includes a first fixed flip 2421 and a second fixed flip 2421 from the membrane side surface 242, 2422 are formed so as to start to extend outward and inward in the horizontal direction, the bottom surface 242s of the pressurizing chamber Cx is formed as a flat horizontal surface. Accordingly, when pneumatic pressure is transmitted from the pneumatic supply part 255x to the pressure chamber Cx from the pressure control part 250, the force Fcx (pushing down the horizontal bottom surface 242s) Since the vertical direction in which the membrane side surface 242 extends and the direction of the force Fcx transmitted by the pressurizing chamber Cx are mutually coincident with each other, the horizontal bottom surface 242s of the pressurizing chamber Cx All of the force is transmitted downward along the membrane side surface 242 and functions as a vertical pressing force Fv for pressing the edge of the wafer to thereby reliably press the edge of the wafer W. [

Hereinafter, the carrier head 2 'of the chemical mechanical polishing apparatus according to the third embodiment of the present invention and the membrane 240' used therein will be described in detail. It should be noted that the same or similar components and functions as those of the first and second embodiments are given the same or similar reference numerals and the description thereof is omitted for clarity of the gist of the third embodiment of the present invention .

7, the membrane 240 'of the carrier head 2' according to the third embodiment of the present invention includes a first fixed flip 2421 'extending outwardly from the upper end of the membrane side 242, Shaped fitting block 248 which is fixed to the retainer ring 230 in FIG. 8 and which is extended from the ring-shaped fitting block 248 and has an end 2481x fixed to the base 220 2481 are provided in the second embodiment.

8, the carrier head 3 ', on which the membrane 240' according to the third embodiment of the present invention is mounted, includes a ring-shaped fitting block 248 of flexible elastic material and a chamber flip 2481, So that the chamber space of the chamber flip 2481 and the first fixed flip 2431 and the second fixed flip 2432 is formed into the pressurizing chamber Cx.

Therefore, in contrast to the configuration of the second embodiment described above, the membrane 240 'according to the third embodiment of the present invention is configured such that the ring-shaped fitting block 248 corresponds to the fitting ring 235 of the second embodiment, Shaped fitting block 248 and the chamber flip 2481 correspond to the membrane 240 of the second embodiment while simultaneously obtaining the advantageous effects obtained by the configuration of the second embodiment, And the positions of the chamber flip 2481 and the first fixed flip 2431 can be firmly fixed in a single operation by the ring-shaped fitting block 248, It is possible to obtain an advantage that assembly is easier than in the second embodiment.

Since the ring-shaped fitting block 248 is integrally formed at the end of the first fixed flip 2431 and the ring-shaped fitting block 248 is inserted and fixed in the recessed portion of the retainer ring 230, The shape and position of the pressure chamber Cx can be stably maintained even when an abnormal phenomenon such as a sudden large air pressure is supplied to the pressure chamber Cx due to the fact that the pressure chambers 2431 are fixed more securely to the retainer ring 230 . As the first fixed flip 2431 is firmly fixed to the retainer ring 230 by the ring fitting block 248, the first fixed flip 2431 is abraded through the gap CL between the retainer ring 230 and the membrane side surface 243 Foreign matter such as particles or slurry can be prevented from flowing into the interior of the carrier head 2 '.

The carrier head 2 'according to the third embodiment of the present invention also includes a first fixed flip 2421 and a second fixed flip 2421 from the membrane side surface 242, similarly to the second embodiment (2, 240) (2422) is extended outwardly and inwardly in the horizontal direction, so that the radial width (X2) of the pressurizing chamber (Cx) is formed to be large. That is, the width X2 of the bottom surface of the pressure chamber Cx is equal to the width X2 of the pressure chamber C5 among the plurality of pressure chambers C1, C2, ..., C5 formed between the membrane and the base. Can be formed larger than the width X5. Accordingly, when the pressure Pi is supplied to the pressurizing chamber Cx through the pneumatic supply portion 255x, the force Fcx multiplied by the bottom surface area of the pressurizing chamber Cx with the supply pressure Pi pushes the bottom face downward And the sum of the pushing forces Fcx is transmitted through the side surface 242 (including the stiffener 271) to press the end edge of the wafer with a large force.

When the pneumatic pressure is transmitted from the pneumatic supply part 255x from the pressure control part 250 to the pressure chamber Cx, the pressure of the pressure chamber Cx A force Fcx pushing the horizontal bottom surface 242s downward is applied and the vertical direction in which the membrane side surface 242 extends and the direction of the force Fcx transmitted by the pressurizing chamber Cx coincide with each other The force pushing the horizontal bottom surface 242s of the pressurizing chamber Cx is entirely transmitted downward along the membrane side surface 242 and functions as a vertical pressing force Fv for pressing the edge of the wafer, So that the end edge of the end portion of the plate is pressed firmly.

The bottom surface of the pressurizing chamber Cx is supported by the first fixed flip 2421 and the second fixed flip 2422 extending on the upper side of the membrane side surfaces 242 and 342 in opposite directions, The vertical pressing force Fv can be acted on the membrane side surfaces 242 and 342 with a large force even if the pressure Pi applied to the pressurizing chamber Cx is small The direction of the force Fcx pushing the bottom surface of the pressurizing chamber Cx coincides with the direction in which the membrane side surfaces 242 and 342 extend and the force Fcx from the pressurizing chamber Cx remains unchanged And is configured to press the edge of the wafer W through the membrane side surfaces 242, 342.

Accordingly, the vertical pressing force Fv as much as intended can be accurately introduced to the edge of the wafer, and the polishing quality at the edge of the wafer can be further improved, and the pressurizing chamber Cx and the pressure chambers C1, ... C5 of the chambers Cx, C1, ... C5 are reduced, the capacity of the pressure control section 250 for supplying the pneumatic pressure to these chambers Cx, C1, ... C5 can be reduced as compared with the prior art, A favorable effect can be obtained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Modified, modified, or improved.

W: wafers C1, C2, C3, C4, C5: pressure chambers
E: excited region F: flat region
220, 320: base 230, 330: retainer ring
235:
240, 340: membrane 241, 341: bottom plate
242, 342: side surfaces 2421, 3421: first fixed flip
2422, 3422: second fixed flip 3423: third fixed flip
243, 343: ring-shaped partition walls 243 ', 343': outermost ring-
247, 347: slope part 260: chamber ring
248: ring type fitting block 2481: chamber flip
271, 272:

Claims (18)

A membrane of a carrier head for a chemical mechanical polishing apparatus,
A bottom plate formed of a flexible elastic material and pressing the plate surface of the wafer,
A side surface having a first fixed flip extending inwardly and a second fixed flip extending in an outward direction, the upper side being formed of a flexible elastic material, being vertically bent at an edge of the bottom plate;
Wherein the polishing pad comprises a polishing pad.
The method according to claim 1,
Wherein the first fixed flip and the second fixed flip begin to extend in a horizontal direction and the top of the side has a flat horizontal surface.
3. The method according to claim 1 or 2,
Wherein said side has a third fixed flip extending outwardly from the middle of said second fixed flip. ≪ RTI ID = 0.0 > 11. < / RTI >
The method of claim 3,
The first fixed flip and the third fixed flip being fixed to a retainer ring surrounding the outside of the carrier head such that a pressure chamber for pressing along the side is formed between the first fixed flip and the third fixed flip ≪ / RTI > wherein the membrane is a porous membrane.
3. The method according to claim 1 or 2,
Wherein a ring-shaped fitting block of a flexible elastic material fixed to the retainer ring of the carrier head is formed at an end of the first fixed flip.
The connector according to claim 5, wherein the ring-
Wherein the chamber flip extends inwardly from a position spaced upwardly from a connection of the first stationary flip. ≪ RTI ID = 0.0 > 18. < / RTI >
3. The method according to claim 1 or 2,
Wherein a ring-shaped stiffener having a higher hardness than the bottom plate is integrally formed on the side surface of the membrane. ≪ Desc / Clms Page number 19 >
A body;
A base rotatably driven with the main body;
A retainer ring which is formed in a ring shape surrounding the periphery of the base and rotatably driven together with the main body, the retainer ring being installed to be supported by the main body and the base;
A membrane according to claim 1 or 2;
Wherein the first fixed flip is fixed to one of the base and the main body and the second fixed flip is fixed to the retainer ring to block a gap between the side surface and the retainer ring Of the carrier head.
9. The method of claim 8,
Wherein the side surface has a third fixed flip extending outward from the middle of the second fixed flip, an end of the second fixed flip and an end of the third fixed flip are fixed to the retainer ring, Wherein the end of the flip is fixed at a position higher than the end of the second fixed flip and a pressure chamber for pressing the side is formed between the first fixed flip and the third fixed flip. Carrier head.
10. The method of claim 9,
Wherein a catch ring is provided in the retainer ring between a position where an end of the first fixed flip is fixed and a position where an end of the third fixed flip is fixed.
10. The method of claim 9,
A plurality of ring-shaped partition walls coupled to the base are formed between the center of the bottom plate and the side surface of the membrane, and a plurality of divided pressure chambers are formed between the base and the membrane;
Wherein the width (x2) of the pressure chambers is larger than the width (x5) of the outermost pressure chambers of the plurality of pressure chambers.
9. The method of claim 8,
And a chamber ring of a flexible elastic material fixed to one of the base and the main body and an outer end fixed to the retainer ring at a position spaced upward from the flat horizontal surface, And a pressure chamber is formed below the chamber ring.
13. The method of claim 12,
A plurality of ring-shaped partition walls coupled to the base are formed between the center of the bottom plate and the side surface of the membrane, and a plurality of divided pressure chambers are formed between the base and the membrane;
Wherein the width (x2) of the pressure chambers is larger than the width (x5) of the outermost pressure chambers of the plurality of pressure chambers.
13. The method of claim 12,
Wherein a fitting ring is provided in the retainer ring between a position where an end of the first fixed flip is fixed and a position where an outer end of the chamber ring is fixed.
9. The method of claim 8,
Wherein a ring-shaped fitting block of a flexible elastic material fixed to the retainer ring is formed at an end of the first fixed flip.
16. The method of claim 15,
Wherein the ring-shaped fitting block is formed with a chamber flip extending inward from a position spaced upward from a connection portion with the first fixed flip, and an end of the chamber flip is fixed to either the main body or the base, Wherein a pressure chamber is formed on the lower side of the carrier head.
17. The method of claim 16,
A plurality of ring-shaped partition walls coupled to the base are formed between the center of the bottom plate and the side surface of the membrane, and a plurality of divided pressure chambers are formed between the base and the membrane;
Wherein the width (x2) of the pressure chambers is larger than the width (x5) of the outermost pressure chambers of the plurality of pressure chambers.
9. The method of claim 8,
Wherein a ring-shaped stiffener having a higher hardness than the bottom plate is integrally formed on the side surface of the membrane.

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