This document claims priorities to Japanese Patent Application Number 2013-235210 filed Nov. 13, 2013 and Japanese Patent Application Number 2014-93840 filed Apr. 30, 2014, the entire contents of which are hereby incorporated by reference.
In a fabrication process of a semiconductor device, a polishing app widely used for polishing a surface of a wafer. The polishing apparatus of this type includes a polishing table for supporting a polishing pad having a polishing surface, a substrate holder, which is called a top ring or a polishing head, for holding the wafer, and a polishing liquid supply nozzle for supplying a polishing liquid onto the polishing surface.
The polishing apparatus polishes the wafer as follows. The polishing table is rotated together with the polishing pad, while the polishing liquid is supplied from the polishing liquid supply nozzle onto the polishing surface. The wafer is held by the substrate holder, and the wafer is rotated about its axis. In this state, the substrate holder presses the surface of the wafer against the polishing surface of the polishing pad so that the surface of the wafer is placed in sliding contact with the polishing surface in the presence of the polishing liquid. The surface of the wafer is planarized by a mechanical action of abrasive grains contained in the polishing liquid and a chemical action of the polishing liquid. Such polishing apparatus is called a CMP (chemical mechanical polishing) apparatus.
During polishing of the wafer, a frictional force acts on the wafer, because the surface of the wafer is in sliding contact with the polishing pad. Therefore, in order to prevent the wafer from disengaging from the substrate holder during polishing of the wafer, the substrate holder includes a retaining ring. This retaining ring is disposed so as to surround the wafer, and is configured to press the polishing pad outside the wafer.
A polishing rate (which is also referred to as a removal rate) of the wafer can vary depending on polishing conditions, such as a load of the wafer on the polishing pad, a load of the retaining ring, rotating speeds of the polishing table and the wafer, and type of polishing liquid. In a case of polishing a plurality of wafers successively, the polishing conditions are typically kept constant in order to obtain the same polishing results. However, as the wafers are polished, an edge profile of each wafer may vary gradually despite the same polishing conditions. Specifically, the polishing rate of an edge portion of the wafer increases in accordance with an increase in the number of polished wafers.
A possible cause of such an increase in the polishing rate is a deformation of the retaining ring.
According to an embodiment, there is provided a substrate holder capable of preventing an increase in a polishing rate of an edge portion of a substrate, even when polishing a plurality of substrates (e.g., wafers) successively. Further, according to another embodiment, there is provided a polishing apparatus and a polishing method using such a substrate holder. Furthermore, according to another embodiment, there is provided a retaining ring for use in the substrate holder.
Embodiments, which will be described below, relate to a substrate holder for holding a substrate, such as a wafer, and more particularly to a substrate holder for use in polishing a surface of a substrate by pressing the substrate against a polishing tool, such as a polishing pad. Further, embodiments relate to a polishing apparatus and a polishing method using such a substrate holder. Furthermore, embodiments relate to a retaining ring for use in the substrate holder.
In an embodiment, there is provided a substrate holder for pressing a substrate a polishing pad, comprising: a top ring body configured to hold the substrate; and a retaining ring disposed so as to surround the substrate held by the top ring body, the taming ring including a pad pressing structure in an annular shape which is to be brought into contact with the polishing pad, and the pad pressing structure having a width in a range of 3 mm to 7.5 mm.
In an embodiment, there is provided a polishing apparatus comprising: a polishing table for supporting a polishing pad; a substrate holder configured to hold a substrate and to press the substrate against the polishing pad; and a polishing liquid supply nozzle configured to supply a polishing liquid onto the polishing pad, the substrate holder including a top ring body configured to hold the substrate, and a retaining ring disposed so as to surround the substrate held by the top ring body, the retaining ring including a pad pressing structure in an annular shape which is to be brought into contact with the polishing pad, and the pad pressing structure having a width in a range of 3 mm to 7.5 mm.
In an embodiment, there is provided a polishing method comprising: rotating a polishing table and a polishing pad; supplying a polishing liquid onto the polishing pad; and pressing a substrate against the polishing pad while pressing a substrate against the polishing pad while a pad pressing structure is surrounding the substrate and pressing the polishing pad, the pad pressing structure being in an annular shape having a width in a range of 3 mm to 7.5 mm.
In an embodiment, there is provided a retaining ring for use in a substrate holder for pressing a substrate against a polishing pad, comprising: a pad pressing structure in an annular shape which is to be brought into contact with the polishing pad, the pad pressing structure having a width in a range of 3 mm to 7.5 mm.
Since the width of the pad pressing structure is small, the pad pressing structure can have a self-restoring function of its shape. That is when the shape of the pad pressing structure is changed as a result of the wear, an area of the pad contact surface of the pad pressing structure is reduced while the pressure of the pad contact surface is increased. When the pressure of the pad contact surface is increased, the pad contact surface is more likely to wear, and as a result the area of the pad contact surface is increased. While such small changes in the pressure and the area of the pad contact surface occur repeatedly, the shape of the pad pressing structure is kept approximately constant. Therefore, the retaining ring having the narrow pad pressing structure can stabilize the polishing rate at the edge portion of the substrate.
Embodiments will be described in detail below with reference to the drawings.
The top ring 1 is configured to hold the wafer W on its lower surface by vacuum suction. The top ring 1 and the polishing table 3 rotate in the same direction as indicated by arrows. In this state, the top ring 1 presses the wafer W against a polishing surface 2a of the polishing pad 2. The polishing liquid is supplied from the polishing liquid supply nozzle 5 onto the polishing pad 2, so that the wafer W is polished by sliding contact with the polishing pad 2 in the presence of the polishing liquid. During polishing of the wafer W, the film thickness sensor 7 rotates together with the polishing table 3 and obtains the film thickness signal while sweeping across a surface of the wafer W as shown by a symbol A. This film thickness signal is an index value indicating the film thickness directly or indirectly, and varies in accordance with a decrease in the film thickness of the wafer W. The film thickness sensor 7 is coupled to a polishing controller 9 so that the film thickness signal is transmitted to the polishing controller 9. This polishing controller 9 is configured to terminate polishing of the wafer W when the film thickness of the wafer W, which is indicated by the film thickness signal, has reached a predetermined target value.
The top ring 1 is coupled to a top ring shaft 11, which is movable vertically relative to a top ring head 16 by a vertically moving mechanism 27. A vertical movement and positioning of the top ring 1 in its entirety relative to the top ring head 16 are achieved by the vertical movement of the top ring shaft 11. A rotary joint 25 is mounted to an upper end of the top ring shaft 11.
The vertically moving mechanism 27 for elevating and lowering the top ring shaft 11 and the top ring 1 includes a bridge 28 for rotatably supporting the top ring shaft 11 through a bearing 26, a ball screw 32 mounted to the bridge 28, a support base 29 supported by pillars 30, and a servomotor 38 mounted to the support base 29. The support base 29 for supporting the servomotor 38 is secured to the top ring head 16 through the pillars 30.
The ball screw 32 has a screw shaft 32a coupled to the servomotor 38 and a nut 32b which is in engagement with the screw shaft 32a. The top ring shaft 11 is configured to move vertically together with the bridge 28. Therefore, when the servomotor 38 is set in motion, the bridge 28 moves vertically through the ball screw 32 to cause the top ring shaft 11 and the top ring 1 to move vertically.
The top ring shaft 11 is further coupled to a rotary cylinder 12 through a key (not shown). This rotary cylinder 12 has a timing pulley 14 on its outer circumferential surface. A top ring motor 18 is secured to the top ring head 16, and a timing pulley 20 is mounted to the top ring motor 18. The timing pulley 14 is coupled to the timing pulley 20 through a timing belt 19. With these configurations, rotation of the top ring motor 18 is transmitted to the rotary cylinder 12 and the top ring shaft 11 through the timing pulley 20, the timing belt 19, and the timing pulley 14 to rotate the rotary cylinder 12 and the top ring shaft 11 in unison, thus rotating the top ring 1 about its own axis. The top ring motor 18, the timing pulley 20, the timing belt 19, and the timing pulley 14 constitute a rotating mechanism for rotating the top ring 1 about its own axis. The top ring head 16 is supported by a top ring head shaft 21 which is rotatably supported by a frame (not shown).
The top ring 1 is configured to hold a substrate, such as the wafer W, on its lower surface. The top ring head 16 is configured to be able to pivot on the top ring head shaft 21, so that the top ring 1, holding the wafer W on its lower surface, is moved from a wafer transfer position to a position above the polishing table 3 by the pivotal movement of the top ring head 16. The top ring 1 is then lowered and presses the wafer W against the polishing surface 2a of the polishing pad 2, while the top ring 1 and the polishing table 3 are rotated and the polishing liquid is supplied onto the polishing pad 2 from the polishing liquid supply nozzle 5 disposed above the polishing table 3. The wafer W is placed in sliding contact with the polishing surface 2a of the polishing pad 2, whereby the surface of the wafer W is polished.
The top ring 1, which serves as the substrate holder, will be described in detail below. Ha 3 is a cross-sectional view of the top ring 1. As shown in
The top ring body 10 has a circular flange 41, a spacer 42 mounted to a lower surface of the flange 41, and a carrier 43 mounted to a lower surface of the spacer 42. The flange 41 is coupled to the top ring shaft 11. The carrier 43 is coupled to the flange 41 through the spacer 42, so that the flange 41, the spacer 42, and the carrier 43 rotate and vertically move together. The top ring body 10, which is constructed by the flange 41, the spacer 42, and the carrier 43, is made of resin, such as engineering plastic (e.g., PEEK). The flange 41 may be made of metal, such as SUS, aluminum, or the like.
A flexible membrane 45, which is brought into contact with a back surface of the wafer W, is attached to a lower surface of the carrier 43 of the top ring body 10. This flexible membrane 45 has a lower surface which serves as a substrate holding surface 45a. The flexible membrane 45 further has annular partition walls 45b which define four pressure chambers: a central chamber 50; a ripple chamber 51; an outer chamber 52; and an edge chamber 53, which are located between the flexible membrane 45 end the top ring body 10. These pressure chambers 50 to 53 are in fluid communication with a pressure regulator 65 via the rotary joint 25, so that pressurized fluid is supplied into these pressure chambers 50 to 53 from the pressure regulator 65. This pressure regulator 65 is configured to be able to regulate pressures in the respective four pressure chambers 50 to 53 independently. Further, the pressure regulator 65 is configured to be able to produce negative pressure in the pressure chambers 50 to 53.
The flexible membrane 45 has a through-hole (not shown) in a position corresponding to the tipple chamber 51 or the outer chamber 52, so that the top ring 1 can hold the substrate on its substrate holding surface 45a by producing the negative pressure in the through-hole. The flexible membrane 45 is made of a highly strong and durable rubber material, such as ethylene propylene rubber (EPDM), polyurethane rubber, silicone rubber, or the like. The central chamber 50, the ripple chamber 51, the outer chamber 52, and the edge chamber 53 are further coupled to a ventilation mechanism (not shown), which can establish a fluid communication between the atmosphere and these four pressure chambers 50 to 53.
The retaining ring 40 is disposed so as to surround the carrier 43 of the top ring body 10 and the flexible membrane 45. This retaining ring 40 is a ring-shaped member which is brought into contact with the polishing surface 2a of the polishing pad 2. The retaining ring 40 is disposed so as to surround a peripheral edge of the wafer W and retains the wafer W therein so as to prevent the wafer W from being separated from the top ring 1 when the wafer W is being polished.
An upper surface of the retaining ring 40 is secured to a drive ring 81. The drive ring 81 has an upper portion coupled to an annular retaining ring pressing mechanism 60, which is configured to exert a uniform downward load on the upper surface of the retaining ring 40 in its entirety through the drive ring 81 to thereby press a lower surface of the retaining ring 40 against the polishing surface 2a of the polishing pad 2.
The retaining ring pressing mechanism 60 includes an annular piston 61 fixed to the upper portion of the drive ring 81, and an annular rolling diaphragm 62 connected to an upper surface of the piston 61. The rolling diaphragm 62 defines a retaining ring pressure chamber 63 therein. This retaining ring pressure chamber 63 is in fluid communication with the pressure regulator 65 through the rotary joint 25.
When the pressure regulator 65 supplies a pressurized fluid (e.g., pressurized air) into the retaining ring pressure chamber 63, the rolling diaphragm 62 pushes down the piston 61, which in turn pushes down the retaining ring 40 in its entirety through the drive ring 81. In this manner, the retaining ring pressing mechanism 60 presses the lower surface of the retaining ring 40 against the polishing surface 2a of the polishing pad 2. Further, when the pressure regulator 65 develops the negative pressure in the retaining ring pressure chamber 63, the retaining ring 40 in its entirety is elevated. The retaining ring pressure chamber 63 is further coupled to a ventilation mechanism (not shown), which can establish a fluid communication between the atmosphere and the retaining ring pressure chamber 63.
The drive ring 81 is removably coupled to the retaining ring pressing mechanism 60. More specifically, the piston 61 is made of a magnetic material, such as metal, and a plurality of magnets 70 are disposed in the upper portion of the drive ring 81. These magnets 70 magnetically attract the piston 61, so that the drive ring 81 is secured to the piston 61 via a magnetic force. The magnetic material of the piston 61 may be corrosion resisting magnetic stainless steel. In another embodiment, the drive ring 81 may be made of a magnetic material, and magnets may be disposed in the piston 61.
The retaining ring 40 is coupled to a spherical bearing 85 through the drive ring 81 and a coupling member 75. The spherical bearing 85 is disposed radially inwardly of the retaining ring 40.
The spokes 78 have one ends fixed to the hub 77, and have the other ends fixed to the drive ring 81. In this embodiment, the hub 77, the spokes 78, and the drive ring 81 are formed integrally. Plural pairs of drive pins 80 and 80 are secured to the carrier 43. The drive pins 80 and 80 of each pair are arranged on both sides of each spoke 78. The rotation of the carrier 43 is transmitted to the drive ring 81 and the retaining ring 40 through the drive pins 80 and 80 to thereby rotate the top ring body 10 and the retaining ring 40 together with each other.
As shown in
A spherical bearing 85 includes an annular inner bearing ring 101, and an annular outer bearing ring 102 which slidably supports an outer circumferential surface of the inner bearing ring 101. The inner bearing ring 101 is coupled to the drive ring 81 and the retaining ring 40 through the coupling member 75. The outer bearing ring 102 is secured to a support member 103, which is secured to the carrier 43. The support member 103 is disposed in a recess 43b which is formed in the central portion of the carrier 43.
The outer circumferential surface of the inner bearing ring 101 has a spherical shape whose upper and lower portions are cut off. A central point (fulcrum) ◯ of this spherical shape is located at the center of the inner bearing ring 101. The outer bearing ring 102 has an inner circumferential surface which is a concave surface shaped so as to fit the outer circumferential surface of the inner bearing ring 101, so that the outer bearing ring 102 slidably supports the inner bearing ring 101. Therefore, the inner bearing ring 101 is tiltable in all directions through 360° relative to the outer bearing ring 102.
The inner bearing ring 101 has an inner circumferential surface which forms a through-hole 101a in which the shaft portion 76 is inserted. The shaft portion 76 is movable relative to the inner bearing ring 101 only in the vertical direction. Therefore, the retaining ring 40, which is coupled to the shaft portion 76, is not allowed to move laterally. That is, the retaining ring 40 is fixed in its lateral position (i.e., its horizontal position) by the spherical bearing 85. The spherical bearing 85 serves as a supporting mechanism capable of supporting or receiving the lateral force (i.e., the force in the radially outward direction of the wafer) applied from the wafer to the retaining ring 40 due to the friction between the wafer and the polishing pad 2 and capable of restricting the lateral movement of the retaining ring 40 (i.e., capable of fixing the horizontal position of the retaining ring 40).
The outer bearing ring 92 is disposed in the recess 43b. The outer bearing ring 92 has a flange portion 92a on its outer circumferential surface. The flange portion 92a is secured to a step of the recess 43b by bolts (not shown), thereby securing the outer bearing ring 92 to the carrier 43 and applying pressure to the intermediate bearing ring 91 and the inner bearing ring 93. The inner bearing ring 93 is disposed on a bottom surface of the recess 43b. This inner bearing ring 93 supports the intermediate bearing ring 91 upwardly so as to form a gap between a lower surface of the intermediate bearing ring 91 and the bottom surface of the recess 43b.
The outer bearing ring 92 has an inner surface 92b, the intermediate bearing ring 91 has an outer surface 91a and an inner surface 91b, and the inner bearing ring 93 has an outer surface 93a. Each of these surfaces 92b, 91a, 91b, and 93a is an approximately hemispheric surface whose center is represented by a fulcrum ◯. The outer surface 91a of the intermediate bearing ring 91 slidably contacts the inner surface 92b of the outer bearing ring 92. The inner surface 91b of the intermediate bearing ring 91 slidably contacts the outer surface 93a of the inner bearing ring 93. The inner surface 92b (sliding contact surface) of the outer bearing ring 92, the outer surface 91a and the inner surface 91b (sliding contact surfaces) of the intermediate bearing ring 91, and the outer surface 93a (sliding contact surface) of the inner bearing ring 93 have a partial spherical shape smaller than an upper half of a spherical surface. With these configurations, the intermediate bearing ring 91 is tiltable in all directions through 360° relative to the outer bearing ring 92 and the inner bearing ring 93. The fulcrum ◯, which is the center of the tilting movement of the intermediate bearing ring 91, is located below the spherical bearing 85.
The outer bearing ring 92, the intermediate bearing ring 91, and the inner bearing ring 93 have respective through-holes 92c, 91c, and 93b funned therein in which the shaft portion 76 is inserted. There is a gap between the through-hole 92c of the outer bearing ring 92 and the shaft portion 76. Similarly, there is a gap between the through-hole 93b of the inner bearing ring 93 and the shaft portion 76. The through-hole 91c of the intermediate bearing ring 91 has a diameter smaller than those of the through-holes 92o and 93b of the outer bearing ring 92 and the inner bearing ring 93 such that the shaft portion 76 is movable relative to the intermediate bearing ring 91 only in the vertical direction. Therefore, the retaining ring 40, which is coupled to the shaft portion 76, is substantially not allowed to move laterally. That is, the retaining ring 40 is fixed in its lateral position (i.e., its horizontal position) by the spherical bearing 85.
The retaining ring 40 includes an annulus 121 and a pad pressing structure 122. The pad pressing structure 122 has an annular shape and extends downwardly from an inner circumferential end of the annulus 121. The annulus 121 and the pad pressing structure 122 are integrally formed from the same material. The pad pressing structure 122 is disposed so as to surround the wafer held on the flexible membrane 45 (see
The pad pressing structure 122 has a lower surface that serves as a pad contact surface 40a to be brought into contact with the polishing pad 2. Specifically, during polishing of the wafer, the pad contact surface 40a of the pad pressing structure 122 is pressed against the polishing pad 2. A plurality of radial grooves 123 extending in the radial direction of the retaining ring 40 are formed in the pad contact surface 40a. These radial grooves 123 are configured to allow the polishing liquid, supplied to the polishing pad 2, to flow from the inside to the outside of the retaining ring 40 and from the outside to the inside of the retaining ring 40. For example, each radial groove 123 has a width of 4 mm.
The retaining ring 40 has a plurality of holes 124 arranged along its circumferential direction (only one of the holes 124 is shown in
A conventional retaining ring has a width of about 15 mm. In contrast, the retaining ring 40 according to an embodiment has a width in the range of 3 mm to 7.5 mm. Since the width of the pad pressing structure 122 is small, the pad pressing structure 122 has a self-restoring function of its shape. The self-restoring function will now be described in detail with reference to
Under the condition that the downward load applied to the retaining ring 40 is constant, as the area of the pad contact surface 40a is reduced, the pressure of the pad contact surface 40a is increased. As a result, as shown in
A lower limit value of the width of the pad pressing structure 122 is 3 mm, which is determined based on a mechanical strength of the pad pressing structure 122.
In the case of the pad pressing structure 122 having the width of 1 mm, the amount of deformation of the pad pressing structure 122 was too large to calculate. In the case of the pad pressing structure 122 having the width of 2 mm, the amount of deformation of the pad pressing structure 122 was large. In the case of the pad pressing structure 122 having the width of not less than 3 mm, the amount of deformation of the pad pressing structure 122 was small. In particular, it can be seen from the graph that the width of less than 3 mm results in a large amount of deformation of the pad pressing structure 122. From these structural analysis results, the lower limit value of the width of the pad pressing structure 122 was determined to be 3 mm.
As can be seen from
The substrate holder according to the above-discussed embodiments can be preferably used for a semiconductor device manufacturing process, such as a shallow trench isolation (STI) process.
The polishing pad 2 has a layered structure including an upper layer made of foamed polyurethane and a lower layer made of a nonwoven fabric. The upper layer has a highly-uniform structure containing fine foam therein and has a modulus of elasticity of about 50 MPa to 100 MPa when the polishing pad 2 is pressed at 4000 hPa to 12000 hPa. The lower layer is an open-cell foam having a modulus of elasticity of about 1.5 MPa to 2.5 MPa when the polishing pad 2 is pressed at 2500 hPa to 4500 hPa. When the taming ring 40 presses the polishing pad 2, the retaining ring 40 sinks down into the polishing pad 2. As a result, a surface pressure at the edge portion of the retaining ring 40 is increased, thereby promoting the wear of this edge portion. Therefore, the retaining ring 40 having the pad pressing structure 122 with the width of not less than 3 mm and not more than 7.5 mm is effective in the case where the polishing pad 2, having the above-described material characteristics, is used.
Polishing conditions of the wafer include a height of the fulcrum of the retaining ring 40 from the surface of the polishing pad 2. In an embodiment, the height of the fulcrum of the retaining ring 40 is in the range of −10 mm to +50 mm. A change in the height of the fulcrum causes a change in an attitude of the retaining ring 40, thus affecting the worn shape of the edge portion of the retaining ring 40. In this case also, the retaining ring 40 having the pad pressing structure 122 with the width of not less than 3 mm and not more than 7.5 mm is effective. When the wafer is transferred between the top ring 1 and a non-illustrated wafer transfer mechanism (or a substrate transfer mechanism), the outer circumferential surface of the retaining ring 40 serves as a guide surface for guiding the wafer transfer mechanism.
In a part of the shallow trench isolation (STI) process, the retaining ring 40 having the pad pressing structure 122 with the width of not less than 3 mm and not more than 7.5 mm is effective because an area of the pad contact surface of the retaining ring 40 does not change greatly.
Although certain embodiments have been described in detail, it should be understood that various changes and modifications may be made without departing from the scope of the technical concept of the present invention.
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2013-235210 | Nov 2013 | JP | national |
2014-093840 | Apr 2014 | JP | national |
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