Embodiments of the present disclosure generally relate to an apparatus and method for polishing and/or planarization of substrates. More particularly, embodiments of the disclosure relate to polishing heads utilized for chemical mechanical polishing (CMP).
Chemical mechanical polishing (CMP) is commonly used in the manufacturing of semiconductor devices to planarize or polish a layer of material deposited on a crystalline silicon (Si) substrate surface. In a typical CMP process, the substrate is retained in a substrate carrier, e.g., polishing head, which presses the substrate towards a rotating polishing pad in the presence of a polishing fluid. Generally, the polishing fluid comprises an aqueous solution of one or more chemical constituents and nanoscale abrasive particles suspended in the aqueous solution. Material is removed across a material layer surface of the substrate in contact with the polishing pad through a combination of chemical and mechanical activity which is provided by the polishing fluid and the relative motion of the substrate and the polishing pad.
The substrate carrier includes a membrane having a plurality of different radial zones that contact the substrate. The membrane may include three or more zones, such as from 3 zones to 11 zones, for example, 3, 5, 7 or 11 zones. The zones are typically labeled from outer to inner (e.g., from zone 1 on the outside to zone 11 on the inside for an 11 zone membrane). Using the different radial zones, pressure applied to a chamber bounded by the backside of the membrane may be selected to control the center to edge profile of force applied by the membrane to the substrate, and consequently, to control the center to edge profile of force applied by the substrate against the polishing pad. Even using the different radial zones, a persistent problem with CMP is the occurrence of an edge effect, i.e., the over- or under-polishing of the outermost 5-10 mm of a substrate. The edge effect can be caused by a sharp rise in pressure between the substrate and the polishing pad around the perimeter portion of the substrate due to a knife edge effect, where a leading edge of the substrate is scraped along a top surface of the polishing pad. Current approaches of applying pressure to the different radial zones result in force being distributed across a large area of the substrate. Such distribution of applied load over a large area is incapable of preventing the edge effect mentioned above.
To mitigate the edge effect and to improve the resulting finish and flatness of the substrate surface, the polishing head includes a retaining ring surrounding the membrane. The retaining ring has a bottom surface for contacting the polishing pad during polishing and a top surface which is secured to the polishing head. Pre-compression of the polishing pad under the bottom surface of the retaining ring reduces the pressure increase at the perimeter portion of the substrate by moving the increased pressure region from underneath the substrate to underneath the retaining ring. However, resulting improvement in uniformity of the perimeter portion of the substrate is generally limited and proves to be inadequate for many applications.
Accordingly, what is needed in the art are apparatus and methods for solving the problems described above.
Embodiments of the present disclosure generally relate to an apparatus and method for polishing and/or planarization of substrates. More particularly, embodiments of the disclosure relate to polishing heads utilized for chemical mechanical polishing (CMP).
In one embodiment, a polishing system includes a carriage arm having an actuator disposed on a lower surface thereof, the actuator including: a piston; and a roller coupled to a distal end of the piston; a polishing pad; and a substrate carrier suspended from the carriage arm and configured to apply a pressure between a substrate and the polishing pad, the substrate carrier including: a housing; a retaining ring coupled to the housing; a membrane coupled to the housing and spanning an inner diameter of the retaining ring, the membrane having a bottom portion configured to contact a substrate and a side portion extending orthogonally to the bottom portion, wherein the side portion includes an annular recess formed along an outer edge of the side portion, and wherein an annular sleeve is disposed in the annular recess; an upper load ring disposed in the housing, wherein the roller of the actuator is configured to contact the upper load ring during relative rotation between the substrate carrier and the carriage arm; a plurality of load pins disposed circumferentially in the housing, each of the plurality of load pins having a proximal end coupled to the upper load ring and a distal end coupled to a lower load ring; and the lower load ring disposed in the housing, the lower load ring having a flange portion coupled to the distal end of each of the plurality of load pins and a body portion extending orthogonally in relation to the flange portion, wherein the body portion contacts the annular sleeve disposed in the membrane; wherein actuation of the actuator is configured to apply a load to a portion of the upper load ring, one or more of the plurality of load pins, lower load ring, annular sleeve and outer edge region of the membrane thereby altering the pressure applied between the substrate and the polishing pad.
So that the manner in which the above recited features of the present disclosure can be understood in detail, a more particular description of the disclosure, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only exemplary embodiments and are therefore not to be considered limiting of the scope of the disclosure, as the disclosure may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.
Before describing several exemplary embodiments of the apparatus and methods, it is to be understood that the disclosure is not limited to the details of construction or process steps set forth in the following description. It is envisioned that some embodiments of the present disclosure may be combined with other embodiments.
As shown in
During substrate polishing, the first actuator 104 is used to rotate the platen 102 about a platen axis A, and the substrate carrier 110 is disposed above the platen 102 and faces there towards. The substrate carrier 110 is used to urge a to-be-polished surface of a substrate 122 (shown in phantom), disposed therein, against the polishing surface of the polishing pad 106 while simultaneously rotating about a carrier axis B. Here, the substrate carrier 110 includes a housing 111, an annular retaining ring 115 coupled to the housing 111, and a membrane 117 spanning the inner diameter of the retaining ring 115. The retaining ring 115 surrounds the substrate 122 and prevents the substrate 122 from slipping from the substrate carrier 110 during polishing. The membrane 117 is used to apply a downward force to the substrate 122 and for loading (chucking) the substrate into the substrate carrier 110 during substrate loading operations and/or between substrate polishing stations. For example, during polishing, a pressurized gas is provided to a carrier chamber 119 to exert a downward force on the membrane 117 and thus a downward force on the substrate 122 in contact therewith. Before and after polishing, a vacuum may be applied to the chamber 119 so that the membrane 117 is deflected upwards to create a low pressure pocket between the membrane 117 and the substrate 122, thus chucking the substrate 122 into the substrate carrier 110.
During polishing, the substrate 122 is urged against the pad 106 in the presence of a polishing fluid provided by the fluid delivery arm 108. The rotating substrate carrier 110 oscillates between an inner radius and an outer radius of the platen 102 to, in part, reduce uneven wear of the surface of the polishing pad 106. Here, the substrate carrier 110 is rotated using a first actuator 124 and is oscillated using a second actuator 126.
Here, the pad conditioner assembly 112 comprises a fixed abrasive conditioning disk 120, e.g., a diamond impregnated disk, which may be urged against the polishing pad 106 to rejuvenate the surface thereof and/or to remove polishing byproducts or other debris therefrom. In other embodiments, the pad conditioner assembly 112 may comprise a brush (not shown).
Operation of the multi-station polishing system 101 and/or the individual polishing stations 100a-c thereof is facilitated by a system controller 136 (
Herein, the memory 142 is in the form of a computer-readable storage media containing instructions (e.g., non-volatile memory), that when executed by the CPU 140, facilitates the operation of the polishing system 101. The instructions in the memory 142 are in the form of a program product such as a program that implements the methods of the present disclosure (e.g., middleware application, equipment software application etc.). The program code may conform to any one of a number of different programming languages. In one example, the disclosure may be implemented as a program product stored on computer-readable storage media for use with a computer system. The program(s) of the program product define functions of the embodiments (including the methods described herein).
Illustrative computer-readable storage media include, but are not limited to: (i) non-writable storage media (e.g., read-only memory devices within a computer such as CD-ROM disks readable by a CD-ROM drive, flash memory, ROM chips or any type of solid-state non-volatile semiconductor memory) on which information is permanently stored; and (ii) writable storage media (e.g., floppy disks within a diskette drive or hard-disk drive or any type of solid-state random-access semiconductor memory) on which alterable information is stored. Such computer-readable storage media, when carrying computer-readable instructions that direct the functions of the methods described herein, are embodiments of the present disclosure.
The external actuator 202 includes a cylindrical housing 204 coupled to a bottom side of the carriage arm 113. The cylindrical housing 204 is longitudinally oriented substantially along the z-axis (e.g., aligned in the direction of gravity). A piston 206 is partially disposed inside the cylindrical housing 204. The piston 206 is actuatable to extend and retract relative to the cylindrical housing 204 substantially along the z-axis (e.g., being vertically movable). In one embodiment, a roller 208 is coupled to a distal end of the piston 206 using a fastener (e.g., a clamp). The roller 208 is configured to contact the housing 111 to transfer a load from the external actuator 202 to the housing 111 or to one or more components of the housing which are described in detail below. The roller 208 enables load transfer to the carrier head 110 during operation (e.g., when the external actuator 202 is stationary and the carrier head 110 is rotating).
The roller 208 contacts an upper load ring 210 disposed in the housing 111. The upper load ring 210 is an annular ring having an upper face 212 and a plurality of lower faces 214 opposite the upper face 212. In some embodiments, the upper load ring 210 has a continuous annular upper face. The upper face 212 is exposed through a top of the housing 111 for maintaining contact with the roller 208 during rotation of the carrier head 110. In some other embodiments (not shown), the upper load ring 210 includes a plurality of arc-shaped segments having a plurality of upper faces 212. Positioned below the upper load ring 210, a plurality of load pins 216 are disposed circumferentially about the carrier axis B of the substrate carrier 110. Each of the plurality of load pins 216 is longitudinally oriented substantially along the z-axis. The plurality of load pins 216 are more clearly depicted in
The plurality of load pins 216 are disposed vertically between the upper load ring 210 and a flange portion 220 of a lower load ring 218. A proximal end of each of the plurality of load pins 216 contacts one of the plurality of lower faces 214 of the upper load ring 210. A distal end of each of the plurality of load pins 216 is coupled to the flange portion 220 of the lower load ring 218 by a fastener (e.g., a machine screw). The lower load ring 218 includes a body portion 222 extending orthogonally to the flange portion 220. The body portion 222 extends substantially along the z-axis. The body portion 222 is disposed radially between the side portion 117b of the membrane 117 and the housing 111. An inner diameter of the body portion 222 is configured to engage the side portion 117b of the membrane 117. The body portion 222 includes a plurality of arc-shaped segments 224 having voids 226 between adjacent segments 224 (
The side portion 117b of the membrane 117 includes an annular recess 117c formed along an outer edge of the side portion 117b. An outer diameter of the recess 117c is less than an outer diameter of the side portion 117b. An annular sleeve 228 is disposed in the recess 117c. An inner diameter of the sleeve 228 is configured to fit the outer diameter of the recess 117c. An outer diameter of the sleeve 228 is greater than the outer diameter of the side portion 117b. A distal end of the body portion 222 of the lower load ring 218 engages a top edge of the sleeve 228 which is radially exposed outside the recess 117c. The segments 224 of the lower load ring 218 concentrate the load applied by each of the plurality of load pins 216 to the underlying circumferential portion of the sleeve 228. The voids 226 (
In operation, actuation of the external actuator 202 extends the piston 206 downward which applies a downforce against the upper load ring 210 via the roller 208. The downforce applied to the upper load ring 210 is ultimately transmitted to the edge of the substrate 122 by a load path which passes through the plurality of load pins 216, the lower load ring 218, the sleeve 228, and the side portion 117b of the membrane 117. Therefore, actuation of the external actuator 202 causes an outer radial portion of the membrane 117 to receive a load in a narrow region of the outer edge of the membrane 117 and substrate 122, which can tend to cause the bottom portion 117a to tilt in relation to the x-y plane. In particular, the narrowly distributed load on the outer edge of the membrane 117 and/or subsequent tilting of the membrane 117 will tend to form a negative taper, which corresponds to greater downward deflection of the bottom portion 117a moving radially outward from a center axis to the outer edge of the membrane 117. The narrowly distributed load on the outer edge of the membrane 117 alters the pressure applied between the substrate 122 and the polishing pad 106.
In certain embodiments, the pressure applied to the edge of the substrate 122 may be locally controlled. In other words, the pressure applied by each of the external actuators 202 may be localized to an arc-shaped region of the substrate 122 disposed underneath one or more active, load applying, external actuators 202. In some embodiments, the length of the arc-shaped region corresponding to localized pressure control may be about 90° or less, such as about 60° or less, such as about 45° or less, such as about 30° or less, such as about 30° to about 90°. Thus, pressure between the substrate 122 and the polishing pad 106 can be locally controlled within distinct circumferential regions by timing actuation of each of the plurality of external actuators 202. By orienting and positioning the external actuators 202 at desired positions or orientations relative to the platen 102 and/or carriage assembly 114, the pressure applied by the external actuators 202 can be applied at any instant in time to one or more desired regions of the membrane 117 during processing. In one example, the one or more desired regions can include portions of the membrane that are near a leading edge or a trailing edge of the carrier head 110 at any instant in time as the carrier head 110 is rotated and moves across the polishing pad 106 during processing. As disclosed herein the carrier head 110 can be moved in a direction that is along the radius of the platen, moved in a direction that is tangential to the radius of the platen, or moved in an arc shaped direction relative to the radius of the platen.
In some other embodiments (not shown), which may be combined with other embodiments described herein, the plurality of load pins 216 may be linear actuators or piezoelectric actuators which are configured to independently apply a downward force against the lower load ring 218.
In some embodiments (not shown), the upper load ring 210 is coupled to the annular sleeve 228. In such embodiments, the upper load ring 210, the plurality of load pins 216, and the lower load ring 218 form one continuous structure, or piece, extending from a load applying shaft of the external actuator 202 to the annular sleeve 228.
In general, the innertube 320 (described in more detail below) is operable to apply a downward force to the outer flange 308 of the flexure plate 304 along the z-axis. The flexure plate 304 also has a flexure section 310 and a body section 312 which are radially adjacent to each other and extending between the inner and outer flanges 306, 308. The flexure section 310 is thinner than each of the inner and outer flanges 306, 308 and the body section 312 such that bending of the flexure plate 304 is primarily concentrated within the flexure section 310.
The innertube 320 is disposed within the housing 111 of the substrate carrier 300. The innertube 320 is annular or arc-shaped. The innertube 320 includes an upper clamp 322 and a lower clamp 324 which are in mating engagement with each to form a pressurized bladder. A connecting element 326 has an upper end contacting the lower clamp 324 and a lower end contacting the outer flange 308 of the flexure plate 304. Pressurization of the innertube 320 exerts a downward force against the outer flange 308 of the flexure plate 304 generating a torsional moment in the flexure plate 304 and causing the outer flange 308 and the body section 312 to deflect toward the decoupled membrane assembly 302. In particular, an annular protrusion 314 formed along a bottom surface of the flexure plate 304 contacts an upper portion 317d of the decoupled membrane assembly 302. Therefore, application of downward force to the flexure plate 304 causes an outer radial portion of the membrane assembly 302, including the bottom portion 317a thereof, to receive a load in a narrow region of the outer edge of the membrane 317 and substrate 122, which can tend to cause the bottom portion 317a to tilt in relation to the x-y plane. In particular, the narrowly distributed load on the outer edge of the membrane 317 and/or subsequent tilting of the membrane 317 will tend to form a negative taper, which corresponds to greater downward deflection of the bottom portion 317a moving radially outward from a center axis to an outer edge of the membrane 317. In some embodiments, the narrowly distributed load received by the membrane assembly 302 can be locally controlled to produce a selectively distributed load on the substrate 122 along an outer radial portion of the membrane 317.
Although only one innertube 320 is illustrated in
In certain embodiments illustrated in
Referring to
The plurality of internal actuators 330 may be similar in structure and function to the external actuator 202. In general, the plurality of internal actuators 330 include a cylindrical housing 332 and a piston 334. The piston 334 is partially disposed inside the cylindrical housing 332. The piston 334 is actuatable to extend and retract relative to the cylindrical housing 332 substantially along the z-axis.
In the embodiments of
While the overall effect of the embodiments of
Each of the embodiments of
Although only one internal actuator 430 is illustrated in
While the foregoing is directed to embodiments of the present disclosure, other and further embodiments of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
This application claims benefit of U.S. provisional patent application Ser. No. 63/112,141, filed Nov. 10, 2020, which is herein incorporated by reference.
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