An abrasive article having an array of abrasive members with a resilient polymeric support that permits each abrasive member to move independently in at least pitch and roll. Each abrasive member includes air bearing features that maintain a fluid bearing (air is the typical fluid) with the substrate. The spacing and pitch of the abrasive members can be adjusted to follow the topography of the substrate to remove a generally uniform layer of material, to engage with the peaks on the substrate to remove target wavelengths of waviness, and/or to remove debris and contamination from the surface of the substrate. The abrasive members can include abrasive features, or can interact with free abrasive particles at an interface with the substrate, or a combination thereof.
Semiconductor wafers are typically fabricated using photolithography, which is adversely affected by inconsistencies or unevenness in the wafer surface. This sensitivity is accentuated with the current drive toward smaller, more highly integrated circuit designs. After each layer of the circuit is etched on the wafer, an oxide layer is put down as the base for the next layer. Each layer of the circuit can create roughness and waviness to the wafer that is preferably removed before depositing the next circuit layer. For many semiconductor applications the chemical mechanical processing (“CMP”) is customized for each layer. A change in a single processing parameter, such as for example, pad design, slurry formulation, or pressure applied by the pad, can require the entire CMP process to be redesigned and recertified.
Magnetic media have similarly stringent planarization requirements as data densities approach 1 Terabyte/inch2 (1 Tbit/in2) and beyond, especially on bit patterned media and discrete track media, such as illustrated in U.S. Pat. Publication 2009/0067082.
CMP is currently the primary approach to planarizing wafers, semiconductors, optical components, magnetic media for hard disk drives, and bit patterned or discrete track media (collectively “substrates”). CMP uses pads to press sub-micron sized particles suspended in the slurry against the surface of the substrate. The nature of the material removal varies with the hardness of the CMP pad. Soft CMP pads conform to the nanotopography and tend to remove material generally uniformly from the entire surface. Hard CMP pads conform less to the nanotopography and therefore remove more material from the peaks or high spots on the surface and less material from low spots.
Traditionally, soft CMP pads have been used to remove a uniform surface layer, such as removing a uniform oxide layer on a semiconductor device. Polishing a substrate with a soft pad also transfers various features from the polishing pad to the substrate. Roughness and waviness is typically caused by uneven pressure applied by the pad during the polishing process. The uneven pressure can be caused by the soft pad topography, the run out of the moving components, or the machined imperfections transferred to the pads. Run-out is the result of larger pressures at the edges of the substrate due to deformation of the soft pad. Soft pad polishing of heterogeneous layered materials, such as semiconductor devices, causes differential removal and damage to the electrical devices.
A CMP pad is generally of a polyurethane or other flexible organic polymer. The particular characteristics of the CMP pad such as hardness, porosity, and rigidity, must be taken into account when developing a particular CMP process for processing of a particular substrate. Unfortunately, wear, hardness, uneven distribution of abrasive particles, and other characteristics of the CMP pad may change over the course of a given CMP process. This is due in part to water absorption as the CMP pad takes up some of the aqueous slurry when encountered at the wafer surface during CMP. This sponge-like behavior of the CMP pad leads to alteration of CMP pad characteristics, notably at the surface of the CMP pad. Debris coming from the substrate and abrasive particles can also accumulate in the pad surface. This accumulation causes a “glazing” or hardening of the top of the pad, thus making the pad less able to hold the abrasive particles of the slurry and decreasing the pad's overall polishing performance. Further, with many pads the pores used to hold the slurry become clogged, and the overall asperity of the pad's polishing surface becomes depressed and matted.
Shortcomings of current CMP processes affect other aspects of substrate processing as well. The sub-micron particles used in CMP tend to agglomerate and strongly adhere to each other and to the substrate, resulting in nano-scale surface defects. Van der Waals forces create a very strong bond between the surface debris and the substrate. Once surface debris form on a substrate it is very difficult to effectively remove them using conventional cleaning methods. Various methods are known in the art for removing surface debris from substrates after CMP, such as disclosed in U.S. Pat. Nos. 4,980,536; 5,099,557; 5,024,968; 6,805,137 (Bailey); U.S. Pat. No. 5,849,135 (Selwyn); U.S. Pat. No. 7,469,443 (Liou); U.S. Pat. No. 6,092,253 (Moinpour et al.); U.S. Pat. No. 6,334,229 (Moinpour et al.); U.S. Pat. No. 6,875,086 (Golzarian et al.); U.S. Pat. No. 7,185,384 (Sun et al.); and U.S. Patent Publication Nos. 2004/0040575 (Tregub et al.); and 2005/0287032 (Tregub et al.), all of which are incorporated by reference, but have proven inadequate for the next generation semiconductors and magnetic media.
Current processing of substrates for semiconductor devices and magnetic media treats uniform surface layer reduction, planarization to remove waviness, and cleaning as three separate disciplines. The incremental improvements in each of these disciplines have not kept pace with the shrinking feature size of features demanded by the electronics industry.
The present disclosure is directed to an abrasive article for lapping or cleaning a surface of a substrate. The abrasive article includes a elastomeric support and a plurality of discrete abrasive members coupled to the elastomeric support so that each abrasive member is adapted to move substantially independently in at least pitch and roll relative to the elastomeric support. A preload mechanism applies a biasing force to each of the abrasive members to bias first surfaces of the abrasive members toward the substrate. One or more air bearing features are located on the first surfaces of the abrasive members to generate hydrodynamic forces during motion of the abrasive article relative to the substrate. The hydrodynamic forces maintain leading edges of the abrasive members further away from the substrate than trailing edges. Abrasive features located at an interface of the first surfaces of the abrasive members lap or clean the substrate in the presence of the hydrodynamic forces.
The present abrasive articles are capable of selectively engaging with nanometer-scale and/or micrometer-scale height variations and micrometer-scale and/or millimeter-scale wavelengths of waviness, on the surfaces of substrates. The spacing, which includes clearance, pitch, and roll, of the abrasive members can be adjusted to follow the topography of the substrate to remove a generally uniform layer of material; to engage with the peaks on the substrate to remove target wavelengths of waviness; and/or to remove debris and contamination from the surface of the substrate.
In one embodiment, the abrasive members are pre-configured with the leading edges further away from the substrate than the trailing edges before application of the hydrodynamic forces. The elastomeric support is preferably bonded to at least a portion of second surfaces of the abrasive members. Sensors are optionally provided on a plurality of the abrasive members.
In one embodiment, a plurality of spring members are embedded in at least one of the abrasive members or the elastomeric support. In one embodiment, the elastomeric support is a non-woven material including a plurality of polymeric fibers and metallic fibers. The elastomeric support is optionally discontinuous. For example, the resilient support may include recesses extending along a portion of second surfaces of the abrasive members.
The preload mechanism is optionally a plurality of a metallic spring members embedded in one or more of the elastomeric support or the abrasive members. The preload mechanism can retain the abrasive members in a cantilevered relationship relative to the elastomeric support.
In another embodiment, a plurality of conduits are fluidly coupled to pressure ports located along first surfaces of the abrasive members. The conduits maintain the abrasive members in a cantilevered configuration relative to the elastomeric support.
The present disclosure is also directed to a method of lapping or cleaning a surface of a substrate. The method includes creating air bearing features on first surfaces of a plurality of abrasive members. Second surfaces of the abrasive members are coupled to a elastomeric support that permits each abrasive member to move independently in at least pitch and roll. Preload mechanisms are positioned to bias the first surfaces of the abrasive members toward the substrate. Abrasive features are positioned at an interface of the first surfaces of the abrasive members and the substrate. The abrasive article is moved relative to the substrate to create hydrodynamic forces that maintain leading edges of the abrasive members further away from the substrate than trailing edges. The abrasive articles lap or clean the substrate.
In one embodiment, a sacrificial layer is applied on the elastomeric support. The abrasive members are molded around distal ends of the preload mechanisms. The sacrificial layer is removed so the abrasive members are in a cantilevered relationship relative to the elastomeric support.
In another embodiment, pressurized gas is delivered to one or more pressure ports on the abrasive members to create a hydrostatic fluid bearing during a start-up phase. The flow of pressurized gas is preferably terminated after the hydrodynamic fluid bearing is formed.
A hydrodynamic and/or hydrostatic bearing is used to provide vertical, pitch and roll stiffness to the abrasive member and to control the spacing and pressure distribution across the air bearing features on the abrasive members. Adjustments to certain variables, such as for example, the spacing (which includes minimal spacing and attitude of the abrasive members), pitch and roll stiffness which control attitude, the preload, and/or the abrasive features can be used to modify the cutting force applied to the substrate.
The elastomeric support applies both a pitch and roll moments to the individual abrasive members, and hence, the air bearing features. If the resilient support is extremely stiff, the air bearing may not be able to form a pitch or roll angle. The preload and preload offset (location where the preload is applied) bias the air bearing toward the substrate.
The individual abrasive members are capable of selectively engaging with nanometer-scale and micrometer-scale height variations and/or micrometer-scale or millimeter-scale wavelengths of waviness on the surface of substrates to perform one or more of the following three overlapping and complementary functions: 1) following the topography of the substrate to remove a generally uniform layer of material; 2) engaging with the peaks on the substrate to remove target wavelengths of waviness; and/or 3) removing debris and contamination from the surface of the substrate. Consequently, the present abrasive articles can be engineered to perform a wide variety of functions, including lapping, planarization, polishing, cleaning, and burnishing substrates.
In connection with performing any of these three functions, the abrasive members may 1) include abrasive features positioned to interact with the substrate, 2) interact with free abrasive particles at the interface with the substrate, or 3) a combination thereof. Free abrasive particles can be used with either topography following or topography removing abrasive members.
While the abrasive features generally have a hardness greater than the substrate, this property is not required for every embodiment since any two solid materials that repeatedly rub against each other will tend to wear each other away. For example, relatively soft polymeric abrasive features molded on the abrasive members can be used to remove surface contaminants or can interact with free abrasive particles to remove material from the surface of a harder substrate. As used herein, “abrasive feature” refers to a portion of an abrasive member that comes in physical contact with a substrate or a contaminant on a substrate, independent of the relative hardness of the respective materials and the resulting cut rate.
Since the abrasive members engage with nanometer-scale and micrometer-scale structures, it is unlikely that any particular embodiment will perform one of the topography following, topography removing, or cleaning functions to the exclusion of the other two. Rather, the present application adopts a probabilistic approach that a particular embodiment is more likely to perform one function, recognizing that the other two functions are also likely being performed in varying degrees.
For example, the topography following abrasive member 1000 of
Various abrasive features are available for the present abrasive members, such as for example, a surface roughness formed on the leading and/or trailing edges of the abrasive members. That surface roughness may include a hard coat, such as for example, diamond-like-carbon. In another embodiment, the abrasive features may be discrete abrasive particles, such as for example, fixed diamonds. In yet another embodiment, the abrasive features may be structured abrasives, discussed further below.
For example, to remove all the wavelengths smaller than a desired value, the dimensions of the abrasive members can be greater than the target wavelengths. The wavelengths are determined by the gas pressure profile generated by the abrasive member and the size of the abrasive member. As a rule of thumb, the smallest circumferential wavelength is about one-fourth the length of the abrasive members.
The dimensions of the abrasive members and the pressure profile due to the hydrostatic and/or hydrodynamic lift (gas and/or liquid) determine the ability of the abrasive member to follow the waviness of the substrate. Assuming that the abrasive members can follow ¼ of its size, then all wavelengths smaller than the ¼ will cause interference with the abrasive members and material removal will ensue due to the interactions. Portions of the abrasive members generate a hydrodynamic lift causing predictable waviness following capability and stabilizing force countering the cutting forces.
The entire content of U.S. application Ser. No. 12/766,473 filed Apr. 23, 2010; U.S. Provisional Patent Application Nos. 61/174,472 filed Apr. 30, 2009; 61/187,658 filed Jun. 16, 2009; 61/220,149 filed Jun. 24, 2009; 61/221,554 filed Jun. 30, 2009; 61/232,425 filed Aug. 8, 2009; 61/232,525 filed Aug. 10, 2009; 61/248,194 filed Oct. 2, 2009; 61/267,031 filed Dec. 5, 2009; and 61/267,030 filed Dec. 5, 2009, is hereby incorporated by reference.
The gimbal assemblies 64 control the static attitude or pitch of each abrasive member 52. The arms 66, cross members 68, and spring member 70 permit the abrasive members 52 to move through at least pitch and roll, while assuring adequate torque is applied to the abrasive members 52. The members 66, 68, and 70 can be configured to promote topography following or topography removing behavior in the abrasive members 52. Various alternate gimbal assemblies are disclosed in U.S. Pat. Nos. 5,774,305; 5,856,896; 6,069,771; 6,459,260; 6,493,192; 6,714,386; 6,744,602; 6,952,330; 7,057,856; and 7,203,033, which are hereby incorporated by reference.
The abrasive members 52 can be fabricated individually as discrete structures or ganged together such as illustrated in
As illustrated in
The dynamic lift 108 causes the abrasive members 52 to assume an attitude or pitch during the relative rotation of a substrate 106. The gimbal assemblies 64 allow the abrasive members 52 to follow the micrometer-scale and/or millimeter-scale wavelengths of waviness (“waviness”) on the substrate 106, while removing nanometer-scale and/or micrometer-scale height variations. Typically, the leading edges 94 of the abrasive members 52 generate a hydrostatic lift countering the forces generated at the interference 104 between the trailing edge 98 and the substrate 106.
Since each of the abrasive members 52 can independently adjust to the waviness of the substrate 106 and maintain a constant cutting force/pressure, the amount of material removed across the substrate 106 is substantially uniform. The present embodiment is particularly well suited to remove a uniform amount of an oxide layer on a semiconductor. The ability of the abrasive members 52 to follow the waviness enables uniform material removal at a level not attainable by conventional CMP processes. In the case of an air bearing, it is desirable to have a boundary layer of lubricant between the abrasive members 52 and the substrate 106.
The preload force 82 is preferably a fraction of the amount used during conventional lapping. The present system and method typically reduces the preload force 82 by an order of magnitude or more. In one embodiment, the preload 82 is in the range of about 0.1 grams/millimeter2 to about 10 grams/millimeter2 of surface being lapped, compared to about 1 kg/millimeter2 for conventional lapping using an oil flooded lapping media.
In one embodiment, the pads 96, 100 can be formed with a crown and cross-curve. The leading edges 94 of the pressure pads 96A, 96B are optionally tapered or stepped to help initiate aerodynamic lift (see, e.g.,
The valleys 81 between the peaks 83 entrain sufficient air to permit the abrasive members 52 to “fly” over the substrate 106, even while the trailing edge 98 is in contact with general texture level 105 of the substrate 106.
The leading edges 94 of the abrasive members 52 are raised above the substrate 106 due to lift 108 acting on fluid bearing surface 86. Engagement of the abrasive members 52 with the substrate 106 is defined by pitch angle 79A and roll angle 79B of the abrasive members 52, and clearance 101 with the substrate 106.
The gimbal assembly 56 (see
In some embodiments, the lift 108 may be purely aerodynamic, creating a stable, uniform fluid bearing. In some embodiments, the lift 108 may be caused, in part, by lubricant 84 on the substrate 106. Abrasive members 52 in full contact with the substrate 106 experience a large amount of forces and vibrations during the polishing process. The cutting forces and moments tend to cause vibrations and bouncing. The preload and gimbal stiffness need to balance the cutting forces. A lubricant 84 is desirable to keep the frictional forces and cutting forces low enough to prevent chattering and the like.
A boundary layer lubrication regime of a thin film a few atoms thick adhered to the surface of the substrate 106 can be used. Alternatively, the lapping can occur in a fully flood environment. Consequently, the fluid dynamic lift 108 according to the present disclosure may be aerodynamic and/or hydrodynamic in nature. Discussion of the lift created by rotating rigid disks is provided in U.S. Pat. Nos. 7,193,805 and 7,218,478, which are hereby incorporated by reference.
The moment 74 generated by the lift 108 is preferably greater than the moment 78 generated by frictional forces 76 at the interface of the pad 100 with the surface of the substrate 106. The trailing edge 98 is located below the general texture level 105 of the substrate 106 during interference lapping. In operation, the interference between the abrasive members 52 and the substrate 106 is essentially continuous. As used herein, “interference lapping” refers to a clearance with an abrasive member that is less than about half a peak-to-valley roughness of a substrate.
In one embodiment, trailing edge 98 is located at about mid-plane 103 of the peak-to-valley roughness 109. Clearance 101 between the mid-plane 103 and the trailing edge 98 is preferably less than half the peak-to-valley roughness 109 of the substrate 106. For example, if the peak-to-valley roughness 109 is about 50 nanometers, the clearance 101 of the abrasive members 52 is less than about 25 nanometers. As used herein, “clearance” refers to a distance between an abrasive member and a mid-plane of a peak-to-valley roughness of a substrate.
In one embodiment, actuators 120 are provided to thermally expand portions of the abrasive member 52 to perform contact detection with the substrate 106. Contact detection refers to bringing an actuated portion of a fluid bearing surface into contact with a substrate, and then decreasing the actuation to establish a desired level of interference with nanometer-scale and/or micrometer-scale height variations on a surface of a substrate. Contact detection between the abrasive member and the substrate can be performed with a variety of methods including, position signal disturbance stemming from fluid bearing modulation, amplitude ratio and harmonic ratio calculations based on Wallace equations, and piezoelectric based acoustic emission sensors. Various actuators and contact detection systems are disclosed in commonly assigned U.S. patent application Ser. No. 12/424,441 (Boutaghou, et al.), filed Apr. 15, 2009, which is hereby incorporated by reference.
The abrasive members 52 have a length 52A measured relative to the motion 107 with substrate 106 that is greater than an approximate wavelength 85 of the peaks 83. The spaces 81 between the peaks 83 entrain sufficient air to permit the abrasive members 52 to “fly” over the substrate 106 at fly height 89 so the trailing edge 98, and in some embodiments the leading edge 94, impacts the peaks 83 or debris 87 located above the fly height 89. The lubricant 84 can be a mono-layer or a flooded environment.
As with the topography following embodiment, the gimbal assembly 56 (see
The abrasive members 52 may include abrasive features at the leading edges 94 and/or trailing edges 98, abrasive particles are interposed between the abrasive members 52 and the substrate 106, or a combination thereof.
As illustrated in
The abrasive features 110 are preferably covered with a hard coat, such as for example, diamond-like-carbon or other hard overcoats depending on the application. The desired peak-to-peak roughness after application of the hard coat varies from about 10 nanometers to about 30 nanometers to provide effective cutting. The peak-to-valley roughness is preferably about 25 nanometers to about 50 nanometers.
Abrasive members 52 constructed from polymers are compatible with diamond-like-carbons. Diamond-like-carbon (“DLC”) thickness varies from about 50 nanometers to about 200 nanometers to provide a hard surface capable of burnishing the substrate. It is highly desirable to generate DLC hardness in the range of 70-90 GPa (Giga-Pascals) to further improve the burnishing process.
In one embodiment the DLC is applied by chemical vapor deposition. As used herein, the term “chemically vapor deposited” and “CVD” refer to materials deposited by vacuum deposition processes, including, but not limited to, thermally activated deposition from reactive gaseous precursor materials, as well as plasma, microwave, DC, or RF plasma arc jet deposition from gaseous precursor materials. Various methods of applying a hard coat to a substrate are disclosed in U.S. Pat. No. 6,821,189 (Coad et al.); U.S. Pat. No. 6,872,127 (Lin et al.); U.S. Pat. No. 7,367,875 (Slutz et al.); and U.S. Pat. No. 7,189,333 (Henderson), which are hereby incorporated by reference.
In another embodiment, nano-diamonds (i.e., with a major diameter less than 1 micrometer) are attached to the pads 96, 100 via existing processes (CVD encapsulation, brazing, adhesives, embedding, etc.). Methods of uniformly dispersing nanometer size abrasive grains are disclosed in U.S. Pat. Pub. No. 2007/0107317 (Takahagi et al.), which is hereby incorporated by reference. Various geometrical features and arrangement of abrasive particles on abrasive articles are disclosed in U.S. Pat. No. 4,821,461 (Holmstrand), U.S. Pat. No. 3,921,342 (Day), and U.S. Pat. No. 3,683,562 (Day), and U.S. Pat. Pub. No. 2004/0072510 (Kinoshita et al), which are hereby incorporated by reference. A two-step adhesion process for attaching diamonds to the pads 96, 100 is disclosed in U.S. Pat. Nos. 7,198,553 and 6,123,612, which are hereby incorporated by reference.
The engineered surface 130 allows for precise stress management between the polished substrate and the nano-features. Such precise stress management yields a predictable surface finish and the gap allows for residual material to be removed. Various engineered surfaces 130 are disclosed in U.S. Pat. No. 6,194,317 (Kaisaki et al); U.S. Pat. No. 6,612,917 (Bruxvoort); U.S. Pat. No. 7,160,178 (Gagliardi et al.); U.S. Pat. No. 7,404,756 (Ouderkirk et al.); and U.S. Publication No. 2008/0053000 (Palmgren et al.), which are hereby incorporated by reference.
In another embodiment, a slurry of abrasive particles is located at the interface 104 (see, e.g.,
As noted above, the abrasive features 110 generally have a hardness greater than the substrate 106, but this property is not required since any two solid materials that repeatedly rub against each other will tend to wear each other away. The abrasive features can be any portion of an abrasive member 52 that forms an interface with a substrate 106 or a contaminant 87 on a substrate 106, independent of the relative hardness of the respective materials and the resulting cut rate.
In some embodiments, the abrasive members 52 are manufactured with one or more sensors to monitor the polishing process, such as for example, acoustic emission or friction sensor. The present interference lapping preferably results in a surface finish or roughness (Ra) of less than about 20 Angstrom, and more preferably less than about 0.2 Angstrom.
In applications using full oil lubrication an interface can be designed to form an oil hydrodynamic film. Typically, the oil film thickness is substantially thicker than an air film thickness due to the viscosity of the lubricant. The height or roughness of the abrasive features on the pads 96, 100 need to be higher than the film thickness to guarantee interference with the substrate 106. Various hydrodynamic features are disclosed in U.S. Pat. No. 6,157,515 (Boutaghou), which is hereby incorporated by reference. Oil hydrodynamic formation requires larger pressures and preloads 82 to be applied to overcome the lift 108 generated by the oil viscosity. Pressure relief features are preferably formed in the pads 96, 100.
In yet another embodiment, a hydrodynamic bearing is not (fully) formed between the abrasive members 52 and the substrate 106. The abrasive members 52 are in full contact with the substrate 106. The gimballing structure 54 allows the abrasive members 52 to follow the waviness of the substrate 106 during polishing, but not the nanometer-scale or micrometer-scale height variations. In the case of a full contacting abrasive members 52, nanometer-scale or micrometer-scale height variations is defined with respect to the length 52A of the abrasive members 52 (see
Instead of applying the preload directly to the abrasive members 158, the preload is applied by the preload structure 152 through the gimbal assemblies 160. This configuration is ideal for low preload applications. Care must be taken not to cause excessive deformation of the gimbal assemblies 160 during preload applications.
As best illustrated in
In one preferred embodiment, a pressure port 218 is located near the leading edges 220 to increase the pitch of the abrasive members 212 for topography following applications. In another embodiment, pressure ports 218 are located at both the leading edges 220 and trailing edges 222 of the abrasive members 212 to configure the pitch for topography removing applications.
The abrasive article 200 is particularly useful when the relative speed between the substrate and the abrasive members 212 is not high enough to form a fluid bearing or hydrodynamic film. The external pressure applied to the abrasive members 212 forms a hydrostatic film capable of following the substrate waviness and countering the cutting forces emanating from the interference between the peaks of the abrasive member 200 and the substrate.
The hydrostatic fluid bearing may be used in combination with a hydrodynamic fluid bearing. In one embodiment, the hydrostatic fluid bearing is used during start-up rotation and/or ramp-down of the abrasive article 200 relative to a substrate.
In another embodiment, the hydrostatic fluid bearing is used simultaneously with a hydrodynamic fluid bearing. The pressure ports 218 located near the inner edge 224 and outer edge 226 of the abrasive article 200 can be pressurized to offset loss of pressure at the fluid bearing in those locations. Consequently, the pressure of the fluid bearing surfaces 214 across width 228 of the abrasive article 200 can be precisely controlled to reduce run out.
In the illustrated embodiment, the fluid bearing features 302 are coextensive with abrasive members 308. The abrasive members 308 are also preferably coextensive with the backing layer 310. The term “coextensive” refers to attachment, bonding, or permeation of the materials comprising the various components 302, 308, and 310. Additional details concerning the general characteristics of the abrasive composites and methods of manufacture can be found in U.S. Pat. No. 5,152,917 (Pieper et al.); U.S. Pat. No. 5,958,794 (Bruxvoort), U.S. Pat. No. 6,121,143 (Messner et al.) and U.S. Patent Publication Nos. 2005/0032462 (Gagliardi et al.) and 2007/0093181 (Lugg et al.), all of which are hereby incorporated by reference.
The abrasive particles 304 are optionally located only at the fluid bearing feature 302A at the trailing edge 316, but can optionally be provided at the fluid bearing features 302B, 302C at the leading edge 318 of the abrasive members 308. The abrasive particles 304 may be non-homogeneously dispersed in a binder 306, but it is generally preferred that the abrasive particles 304 are homogeneously dispersed in the binder.
The abrasive particles 304 may be associated with at least one fluorochemical agent. The fluorochemical agent may be applied to the surface of the abrasive particles 304 by mixing the particles in a fluid containing one or more fluorochemical agents, or by spraying the one or more fluorochemical agents onto the particles. The fluorochemical agents associated with abrasive particles may be reactive or unreactive.
Fine abrasive particles 304 are preferred for the construction of the fluid bearing features 302. The size of the abrasive particles is preferably less than about 1 micrometer and typically between about 10 nanometers to about 200 nanometers. The size of the abrasive particle 304 is typically specified to be the longest dimension. In almost all cases there will be a range or distribution of particle sizes. In some instances, it is preferred that the particle size distribution be tightly controlled such that the resulting fixed abrasive article provides a consistent surface finish on the wafer. The abrasive particles may also be present in the form of an abrasive agglomerate. The abrasive particles in each agglomeration may be held together by an agglomerate binder. Alternatively, the abrasive particles may bond together by inter-particle attraction forces. Examples of suitable abrasive particles 304 include fused aluminum oxide, heat treated aluminum oxide, white fused aluminum oxide, porous aluminas, transition aluminas, zirconia, tin oxide, ceria, fused alumina zirconia, or alumina-based sol gel derived abrasive particles.
The backing layer 310 preferably includes a plurality of areas of weakness 314 that permit the abrasive members 308 to gimbal (i.e., pitch, roll, and yaw) with respect to the backing layer 310. The areas of weakness 314 can be perforations, slits, grooves, and/or slots formed in the backing layer 310. The areas of weakness 314 also permit the passage of the liquid medium before, during, or after use.
The backing layer 310 is preferably uniform in thickness. A variety of backing materials are suitable for this purpose, including both flexible backings and backings that are more rigid. Examples of typical flexible abrasive backings include polymeric film, primed polymeric film, metal foil, cloth, paper, vulcanized fiber, nonwovens and treated versions thereof and combinations thereof. One preferred type of backing is a polymeric film. Examples of such films include polyester films, polyester and co-polyester films, microvoided polyester films, polyimide films, polyamide films, polyvinyl alcohol films, polypropylene film, polyethylene film, and the like. The thickness of the polymeric film backing generally ranges between about 20 to about 1000 micrometers, preferably between about 50 to about 500 micrometers.
A preferred method for making the abrasive composites 312 having precisely shaped abrasive composites 312 is described in U.S. Pat. No. 5,152,917 (Pieper et al) and U.S. Pat. No. 5,435,816 (Spurgeon et al.), both incorporated herein by reference. Other descriptions of suitable methods are reported in U.S. Pat. Nos. 5,437,754; 5,454,844 (Hibbard et al.); U.S. Pat. No. 5,437,754 (Calhoun); and U.S. Pat. No. 5,304,223 (Pieper et al.), all incorporated herein by reference.
Production tools for making the abrasive members 308 may be in the form of a belt, a sheet, a continuous sheet or web, a coating roll such as a rotogravure roll, a sleeve mounted on a coating roll, or die. The production tool may be made of metal, (e.g., nickel), metal alloys, or plastic. The production tool is fabricated by conventional techniques, including photolithography, knurling, engraving, hobbing, electroforming, or diamond turning. For example, a copper tool may be diamond turned and then a nickel metal tool may be electroplated off of the copper tool. Preparations of production tools are reported in U.S. Pat. No. 5,152,917 (Pieper et al.); U.S. Pat. No. 5,489,235 (Gagliardi et al.); U.S. Pat. No. 5,454,844 (Hibbard et al.); U.S. Pat. No. 5,435,816 (Spurgeon et al.); PCT WO 95/07797 (Hoopman et al.); and PCT WO 95/22436 (Hoopman et al.), all incorporated herein by reference. In an alternate embodiment, the abrasive members 308 are used in combination with the gimbal mechanism such as disclosed in
Due to the rigidity of the abrasive members 308, a preload 322 can be applied directly to rear surfaces 324 of the backing layer 310 opposite the abrasive members 308, such as for example, the preload mechanism 56 illustrated in
In one embodiment, one or more protrusions 326 are optionally located near leading edge 318 to prevent the fluid bearing surfaces 302B, 302C from impacting the substrate. The protrusions 326 can be created from a variety of materials, such as for example, diamond-like-carbon.
The grooves 354 reduce the fly height of the abrasive members 358. In applications where the fluid is a liquid, the grooves 354 permit a low fly height and/or a low preload. The grooved abrasive members 358 are particularly well suited to fully flooded applications.
The depth of the grooves 354 must be sufficient to reduce hydrodynamic pressure between the abrasive members 358 and the substrate. In most cases, the grooves 354 have a depth of greater than about 20 micrometers.
By reducing the hydrodynamic film, it is possible to use lubricants with a higher viscosity and/or maintain a low preload on each abrasive member 358, while still achieving interference with the substrate. In some applications, the grooves 354 allow a reduction in the hydrodynamic film while allowing the use of nano-scale diamonds attached to the fluid bearing features 352.
In one embodiment, nano-scale diamonds attached to a polymeric film, such as illustrated in
Designing length 360 of the abrasive members 358 to be greater than the target wavelength permits the abrasive members 358 to interact with the peaks of the waviness for topography removing applications. Alternatively, reducing the length 360 will cause the abrasive members 358 to follow the contour of the waviness and provide more uniform material removal for topography following applications.
The grooves 354 also permit the fly height to be engineered for particular applications. Assuming all other processing variables are held constant, increasing the size or number of grooves 354 reduces fly height, and hence, increases interference between the substrate.
The fly height of the abrasive members 358 above the substrate can also be engineered, such as by changing the size and shape of the fluid bearing features 352. Some variables critical to fly height include the size and shape of gap 362 between the fluid bearing features 352A, 352B, the length 364 and width 366 of the fluid bearing features 352A, 352B, and the length 368 and width 370 of the fluid bearing features 352C.
In one embodiment, a series of different abrasive articles 350 are designed with different sized abrasive members 358 and/or fluid bearing features 352 used to polish a substrate. For example, the abrasive article 350 may initially target peaks only, followed by an abrasive article 350 designed to follow the contour.
In the embodiment of
In the embodiment of
Leading edge 562 of the abrasive member 552 includes a pair of fluid bearing pads 564A, 564B (collectively “564”) each with at least one associated pressure port 566A, 566B. Trailing edge 570 also includes a pair of fluid bearing pads 572A, 572B (collectively “572”) and associated pressure ports 566C, 566D. The fluid bearing surfaces 574 on the trailing edge 570 enhance the stability of the abrasive member 552 at the interface with a surface defect.
The fluid bearing pads 572 on the trailing edge 570 have less surface area than the fluid bearing pads 564 at the leading edge 562. Consequently, the leading edge 562 typically flies higher than the trailing edge 570, which sets the pitch of the abrasive member 552 relative to the substrate 558 (see, e.g.,
The hybrid abrasive member 552 can operate with a hydrostatic fluid bearing and/or a hydrodynamic fluid bearing. The hydrostatic pressure ports 566 apply lift to the abrasive member 552 prior to movement of the substrate 558. The lift permits clearance 556 to be set before the substrate 558 starts to move. Consequently, preload 612 does not damage the substrate 558 during start-up. Once the substrate 558 reaches its safe speed and the hydrodynamic fluid bearing is fully formed, the hydrostatic fluid bearing can be reduced or terminated. The procedure can also be reversed at the end of the polishing process.
In another embodiment, both the hydrostatic and hydrodynamic fluid bearings are maintained during at least a portion of the polishing process. The pressure ports 566 can be used to supplement the hydrodynamic bearing during the polishing process. For example, the pressure ports 566 may be activated to add stiffness to the fluid bearing during initial passes over the substrate 558. The hydrostatic portion of the fluid bearing is then reduced or terminated part way through the polishing process. The pressure ports 566 can also be used to adjust or fine tune the attitude and/or clearance of the abrasive members 552 relative to the substrate 558.
As best illustrated in
Springs 610 transfer the preload 612 from the preload structure 602 to each of the gimbal mechanisms 590. The externally applied load 612, the geometry of the hydrostatic bearing 564, 572, and the external pressure control the desired spacing 556 between the abrasive members 552 and the substrate 558.
Holder structure 620 is attached to the preload structure 602 by stand-offs 622. The holder structure 620 sets the preload 624 applied on each abrasive member 552 and limits the deformation of the gimbal mechanisms 590 in order to avoid damage while the individual preload 624 is applied. An adhesive layer (not shown) attaches the abrasive members 552 to the gimbal box-like structure 594. The external preload 612 applied to the array of abrasive members 552 is greater than or equal to the preloads 624 generated by the independently suspended abrasive members 552 in order to allow the gimbal mechanisms 590 to comply with the substrate 558 and not interfere with the holder structure 620.
Alternate hydrostatic slider height control devices are disclosed in commonly assigned U.S. Provisional Patent Application Ser. No. 61/220,149 entitled Constant Clearance Plate for Embedding Diamonds into Lapping Plates, filed Jun. 24, 2009 and Ser. No. 61/232,425 entitled Dressing Bar for Embedding Abrasive Particles into Substrates, which are hereby incorporated by reference. A mechanism for creating a hydrostatic fluid bearing for a single abrasive member attached to a head gimbal assembly is disclosed in commonly assigned U.S. Provisional Patent Application Ser. No. 61/172,685 entitled Plasmon Head with Hydrostatic Gas Bearing for Near Field Photolithography, filed Apr. 24, 2009, which is hereby incorporated by reference.
Controlling the magnitude of the pressure applied to the abrasive members changes the clearance between the substrate and the abrasive members. The frequency response of the system is independent of the compliance of the material selected for the abrasive member but can be engineered by the selection of the gimballing mechanism, including the hydrostatic bearing design. The pressure generated by the hydrostatic bearing contributes to forming pitch, z-height, and roll forces that counter the cutting forces emanating from surface defects interaction and potential contact with the substrate.
The conditions promoting hydrodynamic lift are bearing design, gas/liquid shearing, and linear velocity of the abrasive member 650 relative to the substrate 658. Such conditions can promote the formation of a fluid film (oil, water, gas) between the abrasive member and the substrate. The relative velocity is obtained by rotating the substrate 658 and/or the abrasive members 650.
Hydrodynamic abrasive article 670 of the present embodiment is best illustrated in
The hydrodynamic fluid film formed at each abrasive member 650 controls the dynamic response of the structure. The frequency response of such system can be designed to be in the 10-100 kHz range, which is sufficient to comply with the substrate surface 668 and to interact with surface debris. The spacing between the polishing surfaces 652C, 652D, 652E can be controlled to cause interaction with surface defects with little to no material removal from the substrate 658. In order for the fluid bearing surfaces 652 to develop a stable interface, the hydrodynamic forces must be greater than external disturbances caused by the interference or contact between the polishing surfaces 652C, 652D, 652E and the surface defects.
The abrasive member 750 preferably forms a contact interface with the substrate, although this embodiment may be used with a hydrodynamic or hydrostatic bearing. Cylinder preload fixture 752 includes a plurality of dimpled spring members 754 that apply an outward radial preload 756 on each gimbal mechanism 758. The preload 756 is transferred by dimple member 760 acting on rear surface 762 of the gimbal mechanisms 758. The gimbal mechanisms 758 are interconnected into a gimbal assembly 764 by support structure 766. The individual abrasive members 768 are attached to the gimbal mechanisms 758.
A hydrostatic bearing can optionally be generated at the interface of the abrasive members 768 and the substrate via external pressurization means, as discussed above. The hydrostatic approach permits the abrasive members 768 to hover over the substrate surface at any desired clearance while still being able to interact and remove surface defects. A stable contacting interface can also be used with the abrasive members 768. The abrasive members 768 can either be a porous sponge-like material or a hard coated slider. The gimbal mechanisms 758 and preload mechanisms 754 permit the abrasive members 768 to follow the run-out and waviness of the substrate while the abrasive members 768 intimately contact and clean the substrate.
Alternate methods of controlling the height of the abrasive members above the substrate are disclosed in commonly assigned U.S. Provisional Patent Application Ser. No. 61/220,149 entitled Constant Clearance Plate for Embedding Diamonds into Lapping Plates, filed Jun. 24, 2009 and Ser. No. 61/232,425 entitled Dressing Bar for Embedding Abrasive Particles into Substrates, which are hereby incorporated by reference. A mechanism for creating a hydrostatic fluid bearing for a single abrasive member attached to a head gimbal assembly is disclosed in commonly assigned U.S. Provisional Patent Application Ser. No. 61/172,685 entitled Plasmon Head with Hydrostatic Gas Bearing for Near Field Photolithography, filed Apr. 24, 2009, which is hereby incorporated by reference.
Controlling the magnitude of the pressure applied to the abrasive members changes the clearance between the substrate and the abrasive members. The frequency response of the system is independent of the compliance of the material selected for the abrasive members but can be engineered by the selection of the gimballing mechanism, including the hydrostatic bearing design. The pressure generated by the hydrostatic bearing contributes to forming pitch, z-height and roll forces that counter the cutting forces emanating from surface defects interaction and potential contact with the substrate.
The leading edge pads 804 are formed with rounded surfaces 816 to promote the redistribution of debris and lubricant. This example of a low contact force abrasive member 800 includes leading edge step 818 that increases lift at the leading edge 802.
Table 1 shows that the leading edge 802 clears the substrate, while the trailing edge 810 is in contact. This approach permits the trailing edge 810 to follow the substrate waviness. The leading and trailing edge pressurization contribute to the stability of the design during asperity interactions and debris removal. This design is ideal for cleaning debris and removing nano level amounts of material in the presence of a thin film lubricant.
Table 2 provides a summary of various performance parameters for the abrasive member as a function of preload.
The height 854 is sufficient to create a positive pressure profile at the top of the pads 844, 850 and a negative suction force at the trailing side 845 of the features 844 in cases of air as a lubricant. The proper selection of the pressure distributions controls the pitch angle of the abrasive member 840 and the minimum spacing above the substrate.
In the case of topography removing, the abrasive member 840 does not follow certain target wavelengths of waviness. The pitch angle of the abrasive member 840 is therefore substantially reduced to cause both the leading edges 842 and the trailing edges 848 to not follow the target wavelengths of waviness and to cause wear of the interacting surfaces.
A simple exercise demonstrates the capability of this design given in Table 3. By varying the externally applied preloads from about 0.1 grams to about 10 grams, a reduction in the pitch angle and spacing is attained, causing a higher level of wear and interactions between both the leading and trailing edges 842, 848 and the substrate. The low pitch angle also inhibits follow of the target wavelengths.
Note that at 5 grams of preload a negative suction force and a total positive pressure is generated to counter the contact force of 2.56 grams and the 5 grams of preload. An increase in preload as shown causes a substantially linear increase in contact force responsible for the removal of material at the substrate.
Table 3 provides a summary of various performance parameters for the abrasive member as a function of preload.
Rails 876 at trailing edge 874 help pressurize the bearing and cause the trailing edge 874 to contact the substrate. Top surfaces 878 of the rails 876 are in direct contact with the substrate if desired. These surfaces 878 can be textured and coated with hard coatings to cause defect removal and burnishing. The rails 876 control the spacing between the abrasive member 870 and the substrate and provide a predictable interference between the trapped free abrasive particles and the substrate.
A series of shaped recessed pads 880 are fabricated at the trailing edge 874 between the rails 876 to interact with the free abrasive particles present in the chemical mechanical polishing slurry. The recesses have a depth 882 of about 10 nanometers to about 50 nanometers relative to rails 876, which is smaller than the diameter of the free abrasive particles. The leading edges 884 of the recessed pads 880 are shaped to allow progressive entrance of the free abrasive particles to the interface of the abrasive member 870 with the substrate.
The design presents a leading edge 884 pressurized zone and a trailing edge 874 pressurized zone. The trailing edge 874 is able to both follow the topography while the recessed pads 880 cause the free abrasive particles to be in intimate contact with the substrate. The resulting contact pressure is substantially uniform and independent of the substrate topography.
One or more button bearings 902, 904 are fabricated at the leading edge 906, such as illustrated in
Additional button bearings 914, 916 are optionally located on the pad 908 to establish a desired spacing profile with the substrate, including pitch, nominal spacing (minimum), and a roll attitude of the abrasive member 900.
The height differential from center 1164 of the fluid bearing structure 1158 to the edge 1166 is preferably about 10 nanometers to about 100 nanometers to permit the fluid bearing to form. The spherical nature of the fluid bearing surface 1158 is desirable for interacting with free abrasive particles contained in slurry for chemical mechanical polishing.
Each abrasive member 1152 includes a plurality of extensions 1168 that form the individual gimbal assemblies 1170. As best illustrated in
Preload members 1176 are positioned between the preload pad 1174 and rear surfaces 1159 of the abrasive members 1152. The preload members 1176 are preferably resilient to permit deflection of the abrasive members 1152 in the vertical direction. The preload members 1176 are preferably attached to either the preload pad 1174 or the abrasive members 1152. In an alternate embodiment, the preload pad 1174 is made of a resilient material. The preload 1184 is applied simply by pushing the entire assembly 1150 against the substrate.
The abrasive members 1152 optionally include one or more cavities or steps 1180 near leading edge 1182 to promote formation of a fluid bearing. By changing the curvature of the fluid bearing surface 1158, the shape or location of the cavities 1180, or a variety of other variables, the abrasive members can be either topography following or topography removing. If the curvature of the fluid bearing surface 1158 is increased above about 100 nanometers, the maximum pressure tends to form at the center 1164. The spherical configuration permits progressive interactions with free abrasives. The spherical shape also allows for a point like contact with desirable topography following properties.
Rear surfaces 1208 of each abrasive member 1202 includes channels 1210 that fluidly communicate with opening 1212 in sealing layer 1214. As best illustrated in
Resilient Support
In the illustrated embodiment, resilient support 1304 is a layer of resilient material and the abrasive members 1302 are discrete structures arranged in a circular array. Each abrasive member 1302 can articulate independently in at least pitch 1336 and roll 1338 (see
The resilient supports of the embodiments discussed herein are a lower cost alternative to mechanical gimbal mechanisms. While some embodiments the resilient supports may lack the frequency response of a mechanical gimbal, the resilient supports are more resistant to vibration or chatter. By modifying the resilient support, pitch and roll stiffness can be engineered for the particular application. The resilient supports can be made using a wide variety of techniques, such as for example, molding, stamping, laser cutting, and can be constructed from one or more layers.
The stiffness of the air bearing is preferably greater than the stiffness of the resilient support 1304, so the dominant factor effecting the engagement of the abrasive members 1302 with substrate 1314 is the air bearing. Once the air bearing is formed the frequency response is typically comparable to that of mechanical gimbals, with greater resistance to harmonic vibration and chatter. Additionally, frequency response is typically less important for some topography removing applications.
In the illustrate embodiment, resilient layer 1304 does not completely decouple pitch and roll displacement of a single abrasive member 1302, as can be done with a mechanical gimbal. The ability to use low-cost molding techniques to make the abrasive article 1300, however, outweighs this limitation for some embodiments.
In one embodiment, the resilient support 1304 is bonded to the abrasive member 1302. As used herein, “bond” or “bonding” refers to, for example, adhesive bonding, solvent bonding, ultrasonic welding, thermal bonding, and the like. In another embodiment, the resilient support 1304 and the abrasive members 1302 are fused together during the molding process.
Preload structures 1306 biases preload member 1308 to transmit preload 1310 to rear surface 1312 of the abrasive members 1302. In the preferred embodiment, each abrasive member 1302 has one or more discrete preload members. The preload members 1308 are preferably embedded or molded in the resilient layer 1304. The stiffness of the air bearing is preferably balanced with the stiffness of preload structure 1306.
The abrasive members 1302 are preferably rigid so that they pivot around distal end 1308A of the preload member 1308. In the illustrated embodiment, the preload member 1308 is a metallic spring member that permits Z-axis 1334 displacement of the abrasive members 1302, although a rigid preload member can also be used (see
As illustrated in
The hydrodynamic forces 1318 are preferably substantially greater than the stiffness of the resilient layer 1304. The pitch angle 1332 is preferably controlled by other factors, such as for example, the configuration of the air bearing features 1316, the speed of the abrasive article 1300 relative to the substrate 1314, and the like.
As discussed herein, the trailing edge 1322 preferably includes abrasive features. The abrasive features can be one or more of an abrasive material attached to the air bearing features 1316, a slurry of free abrasive particles located at the interface of the air bearing features 1316 and the substrate 1314, air bearing features 1316 made from abrasive particles disbursed in a binder, nano-scale roughened surface of the air bearing features 1316 coated with a hard coat, or nano-scale diamonds attached to the air bearing features 1316 at trailing edges 1322 of the abrasive members 1302, or a combination thereof. The substrate 1314 can be a wafer, a wafer-scale semiconductor, magnetic media for hard disk drives, bit patterned or discrete track media, a convention disk for a hard disk drive, or any other substrate.
In another embodiment, one or more heaters 1392 can be included to thermally expand the abrasive members 1374 as a mechanism of controlling the gap 1376 and/or to shape the contact surface 1394. Various arrangements of heaters are disclosed in U.S. Pat. Nos. 7,428,124 and 7,430,098 (Song, et al.); U.S. Pat. No. 7,388,726 (McKenzie et al.); and U.S. Pat. Publication No. 2007/0035881 (Burbank et al.), which are hereby incorporated by reference.
In the illustrated embodiment, circuit layer 1380 is located between the preload structure 1382 and the resilient layer 1384. The electrical connection between the circuit layer 1380 and the sensors 1372 can be made using a separate electrical conductor 1386 embedded in the resilient layer 1384. In another embodiment, preload member 1388 acts as the electrical conductor 1386.
Additional circuitry or electrical devices 1390 can be located in the circuit layer 1380 or in the abrasive members 1374, such as for example, ground planes, power planes, transistors, capacitors, resistors, RF antennae, shielding, filters, memory devices, embedded IC, and the like. In one embodiment, the electrical devices 1390 can be formed using printing technology, adding intelligence to the abrasive members 1374. The availability of printable silicon inks provides the ability to print electrical devices 1390, such as disclosed in U.S. Pat. No. 7,485,345 (Renn et al.); U.S. Pat. No. 7,382,363 (Albert et al.); U.S. Pat. No. 7,148,128 (Jacobson); U.S. Pat. No. 6,967,640 (Albert et al.); U.S. Pat. No. 6,825,829 (Albert et al.); U.S. Pat. No. 6,750,473 (Amundson et al.); U.S. Pat. No. 6,652,075 (Jacobson); U.S. Pat. No. 6,639,578 (Comiskey et al.); U.S. Pat. No. 6,545,291 (Amundson et al.); U.S. Pat. No. 6,521,489 (Duthaler et al.); U.S. Pat. No. 6,459,418 (Comiskey et al.); U.S. Pat. No. 6,422,687 (Jacobson); U.S. Pat. No. 6,413,790 (Duthaler et al.); U.S. Pat. No. 6,312,971 (Amundson et al.); U.S. Pat. No. 6,252,564 (Albert et al.); U.S. Pat. No. 6,177,921 (Comiskey et al.); U.S. Pat. No. 6,120,588 (Jacobson); U.S. Pat. No. 6,118,426 (Albert et al.); and U.S. Pat. Publication No. 2008/0008822 (Kowalski et al.), which are hereby incorporated by reference.
In one embodiment, sacrificial layer 1408, such as for example a photo mask, is then applied to surface 1410 of the resilient support 1406. The abrasive members 1402 are then molded over the preload member 1404 protruding from the sacrificial layer 1408. Thickness 1412 of the sacrificial layer 1408 determines gap 1414 (see
As illustrated in
In an alternate embodiment illustrated in
In one embodiment, the thickness 1412 is selected to permit the abrasive members 1402 to assume a desired pitch angle 1420 relative to substrate 1416. As illustrated in FIG. 62, leading edge 1418 contacts, or is adjacent to, the layer 1406 after formation of an air bearing. The layer 1406 acts to limit or resist further increases in the pitch angle 1420. The interaction of the leading edge 1418 with the layer 1406 attenuates vibration of the abrasive member 1402.
As illustrated in
In the illustrated embodiment, the tension member 1456 is highly flexible and provides minimal resistance to the abrasive members 1452 pivoting on pivot structure 1458. In one embodiment, the tension member 1456 is an extension of pivot structure 1458, instead of a separate structure. In another embodiment, tension member 1456 is a polymeric structure, such as a monofilament.
In the preferred embodiment, a plurality of spring structures 1460 are embedded in resilient support layer 1454. The spring structures 1460 are preferably located along centerline of the abrasive members 1452 (x-axis) so as to reduce resistance to roll 1462. Although the spring structures 1460 are illustrated as coil springs, a variety of other spring structures may be used, such as for example, leaf springs, flat springs, cantilever springs, and the like. Alternatively, the resilient supports 1460 can be embedded in the abrasive members 1452 and/or the resilient support layer 1454. In yet another embodiment, the spring structures 1460 are elastomeric members.
In the illustrate embodiment, the non-woven resilient support 1494 is non-planar. Resilient protrusion 1498 is preferably embedded in the abrasive members 1492, such as by overmolding, to create gap 1500 to facilitate pivoting. Preload member 1502 is optionally embedded in layer 1504 for greater stability. In one embodiment, layer 1504 includes a plurality of openings 1506 through which debris abraded from substrate 1508 is removed from interface 1510 by force of vacuum.
Changing the geometry of the projections 1526 permits the pitch and roll stiffness to be modified for the particular application. In particular, increase the width of the projections 1526 increases roll stiffness. In one embodiment, additional projections 1526 are formed in the resilient support 1524 that engage with side edges of the abrasive members 1522 to enhance roll stiffness.
The abrasive members 1522 preferably have dimension 1532 in at least one direction that is less then corresponding dimension 1534 of the recess 1528. Consequently, during engagement with substrate 1536, only the resilience of the cantilevered projections 1526 resist displacement of the abrasive members 1522. Preload member 1538 is preferably embedded in layer 1540.
A hydrostatic bearing may be used in combination with a hydrodynamic fluid bearing, such as during start-up rotation and/or ramp-down of the abrasive article 1570 relative to a substrate. The hydrostatic bearing controls the interface with the substrate 1582 until hydrodynamic air bearing is at least partially formed, as discussed above. Thereafter, the hydrostatic bearing is preferably reduced or terminated.
Where a range of values is provided, it is understood that each intervening value, to the tenth of the unit of the lower limit unless the context clearly dictates otherwise, between the upper and lower limit of that range and any other stated or intervening value in that stated range is encompassed within the present embodiments. The upper and lower limits of these smaller ranges which may independently be included in the smaller ranges is also encompassed within the disclosure, subject to any specifically excluded limit in the stated range. Where the stated range includes one or both of the limits, ranges excluding either both of those included limits are also included in this disclosure.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which these inventions belong. Although any methods and materials similar or equivalent to those described herein can also be used in the practice or testing of the present inventions, the preferred methods and materials are now described. All patents and publications mentioned herein, including those cited in the Background of the application, are hereby incorporated by reference to disclose and describe the methods and/or materials in connection with which the publications are cited.
The publications discussed herein are provided solely for their disclosure prior to the filing date of the present application. Nothing herein is to be construed as an admission that the present inventions are not entitled to antedate such publication by virtue of prior invention. Further, the dates of publication provided may be different from the actual publication dates which may need to be independently confirmed.
Other embodiments of the invention are possible. Although the description above contains much specificity, these should not be construed as limiting the scope of the invention, but as merely providing illustrations of some of the presently preferred embodiments of this invention. It is also contemplated that various combinations or sub-combinations of the specific features and aspects of the embodiments may be made and still fall within the scope of the inventions. It should be understood that various features and aspects of the disclosed embodiments can be combined with or substituted for one another in order to form varying modes of the disclosed inventions. Thus, it is intended that the scope of at least some of the present inventions herein disclosed should not be limited by the particular disclosed embodiments described above.
Thus the scope of this invention should be determined by the appended claims and their legal equivalents. Therefore, it will be appreciated that the scope of the present invention fully encompasses other embodiments which may become obvious to those skilled in the art, and that the scope of the present invention is accordingly to be limited by nothing other than the appended claims, in which reference to an element in the singular is not intended to mean “one and only one” unless explicitly so stated, but rather “one or more.” All structural, chemical, and functional equivalents to the elements of the above-described preferred embodiment that are known to those of ordinary skill in the art are expressly incorporated herein by reference and are intended to be encompassed by the present claims. Moreover, it is not necessary for a device or method to address each and every problem sought to be solved by the present invention, for it to be encompassed by the present claims. Furthermore, no element, component, or method step in the present disclosure is intended to be dedicated to the public regardless of whether the element, component, or method step is explicitly recited in the claims.
The present application is a continuation-in-part of U.S. application Ser. No. 12/766,473, entitled Abrasive Article with Array of Gimballed Abrasive Members and Method of Use, filed Apr. 23, 2010, which claims the benefit of U.S. Provisional Patent Application Nos. 61/174,472 entitled Method and Apparatus for Atomic Level Lapping, filed Apr. 30, 2009; 61/187,658 entitled Abrasive Member with Uniform Height Abrasive Particles, filed Jun. 16, 2009; 61/220,149 entitled Constant Clearance Plate for Embedding Diamonds into Lapping Plates, filed Jun. 24, 2009; 61/221,554 entitled Abrasive Article with Array of Gimballed Abrasive Members and Method of Use, filed Jun. 30, 2009; 61/232,425 entitled Constant Clearance Plate for Embedding Abrasive Particles into Substrates, filed Aug. 8, 2009; 61/232,525 entitled Method and Apparatus for Ultrasonic Polishing, filed Aug. 10, 2009; 61/248,194 entitled Method and Apparatus for Nano-Scale Cleaning, filed Oct. 2, 2009; 61/267,031 entitled Abrasive Article with Array of Gimballed Abrasive Members and Method of Use, entitled Dec. 5, 2009; and 61/267,030 entitled Dressing Bar for Embedding Abrasive Particles into Substrates, filed Dec. 5, 2009, all of which are hereby incorporated by reference.
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Child | 12784908 | US |