The present invention relates to a cleaning cup system for use with chemical mechanical planarization (CMP) apparatus and, more particularly, to a cleaning cup system for removing particulate matter from a conditioner head (including the conditioning abrasive disk/brush) by the application of high velocity streams of cleaning fluids.
Chemical mechanical planarization (CMP) is a process well-known in the art for processing surfaces of a semiconductor wafer. Planarization, in effect, polishes away a portion of the wafer's surface to form an ultra-smooth exposure upon which additional processing layers may be formed. CMP utilizes both a “mechanical” polishing pad to convey pressure which, in combination with tightly-controlled particulate material (component of polishing slurry) abrasively remove some material, as well as at least one chemically-reactive agent (component of polishing slurry) to initiate an “etching” or softening of surface materials. Over time, the polishing pad is known to experience buildup of excess compacted polishing slurry solids, hardened urethane pad materials (in response to heat, mechanical work, process chemicals, etc.), reacted materials and wafer debris, globally referred to as “glazing”. In the art, therefore, it has become desirable to continually clean (“condition” or “dress”) the polishing pad by removing trapped slurry and unmatting (re-expanding and/or texturing with mechanically ‘cut’ furrows) the pad material.
A number of conditioning procedures and apparatus have been developed. One conventional conditioner comprises an arm for holding a conditioner head with an abrasive disk facing the polishing pad. A bearing system rotatably supports the abrasive disk at the end of the arm. The abrasive disk rotates against the polishing pad to physically abrade the polishing pad and remove the glazing layer from the pad's surface.
While the abrasive disk is rotating against the polishing pad, slurry will tend to coat the edges and surfaces of the abrasive conditioning disk, as well as splash on the conditioner head itself. When the conditioner head is not operating (for example, between polishing operations), the slurry remaining on the abrasive disk and conditioner head can build up to form a hardened, caked surface. During the next polishing operation, therefore, the residual slurry film and particles may dislodge and fall onto the polishing pad and scratch the surface of the wafer being processed. The build-up or “fouling” commonly forms between abrasive grains, which service to decrease the abrasive particle exposure, which over time can reduce the abrasive penetration and thereby effectiveness of the conditioner. In systems where the chemistry may be modified between polishing and/or conditioning cycles, chemically dislodged material may further result in cross-contaminating subsequent wafers being processed.
The prior art has proposed various types of “cleaning cups” in which the conditioner head may be positioned when not being used, where the cups can be likened to a bath for the head, maintaining any slurry in a sufficiently liquid state to avoid the formation of hardened slurry particles during subsequent conditioning processes.
Initial prior art “cleaning cups” consisted of a bath of deionized water (or another cleaning fluid), which would hold the conditioner head in a submerged position between conditioning operations. U.S. Pat. No. 6,217,430 issued to R. Koga et al. on Apr. 17, 2001 discloses a prior art cleaning cup improvement over this basic arrangement, using a spray nozzle for spraying a cleaning solution on the top side of the conditioner head while the underside of the head (supporting the abrasive disk) remain submerged in the cleaning cup bath. U.S. Pat. No. 6,481,446 issued to M-S Yang et al. on Nov. 19, 2002 discloses an alternative cleaning cup structure, in this case including an apertured bottom support for allowing an injected inert gas to bubble up through the cleaning bath and assist in the removal of particles that are sticking to the abrasive conditioning disk. In a further example, U.S. Pat. No. 7,025,663 issued to T-B Kim on Apr. 11, 2006 describes a cleaning cup including a similar bubbler structure as taught by Yang et al., used in combination with a U-shaped spraying pipe that is provided with a plurality of nozzles to spray downward onto the conditioner head.
While these various prior art arrangements are considered improvements over the conventional “static bath”, they have not been successful in completely removing all of the particulate residue from the conditioning head. It has been found that some of the slurry debris will remain adhered to the conditioner head, including the abrasive surface, resulting in a condition now referred to as “disk fouling”—the remaining residue causing a mechanical change in the abrasive quality of the conditioner head surface.
Thus, a need remains in the art for an arrangement that will successfully remove most, if not all, of the adherent residue from a CMP system conditioner head.
The needs remaining in the prior art are addressed by the present invention which relates to a cleaning cup system for use with CMP apparatus and, more particularly, to a cleaning cup system for removing residue from a conditioner head (including the conditioning abrasive surface) by the application of a plurality of separate high velocity streams of cleaning fluids which contain sufficient energy to atomize upon contact with the end effector surfaces and dislodge the remaining residue.
In accordance with the present invention, a cleaning cup apparatus is formed to include a plurality of high velocity spray jets for directing cleaning fluid onto the bottom (i.e., abrasive surface), sides and top of a conditioner head, as well as the end effector to which the conditioner head is attached. The plurality of jets includes a spray outlet in the base of the cleaning cup for directing a spray of cleaning fluid upward onto the exposed surface of the abrasive. The velocity of the upward-directed spray having a sufficient energy and/or angle to break the bonds holding the residue in place. Additional spray jets are formed as vertical spray stems and used to direct sprays of cleaning fluid onto the top and sides of the conditioner head. The cleaning cup itself is formed to include a pair of deflectors, disposed between the spray stems, that are used to re-direct the cleaning fluid from the perimeter of the cup back onto the sides of the conditioner head.
In one embodiment, the spray outlet within the base of the cleaning cup is formed as a knife spray for directing a sheet of high velocity spray upward onto the abrasive surface. In systems where the conditioner head is rotated during cleaning, a single knife formed across a radius of the base may be used to efficiently clean the entire abrasive surface. In systems where the conditioner head remains stationary, a plurality of spray knives may be used. Alternatively, a shower head type of spray fixture may be used to direct high velocity streams upward onto the abrasive surface. In any of these arrangements, the velocity of the cleaning fluid spray must be sufficient to overcome the surface tension associated with the “static bath” of cleaning fluid held within the cleaning Cup.
In a further embodiment of the present invention, the spray outlet exhibits a particular geometry that will induce turbulence in the “static bath” held within the cleaning cup. The turbulence creates additional flow toward the spray outlet, adding volume to the spray and reducing the force required to escape the surface tension of the bath. Alternatively, the bath can be foamed by injecting gas, as in the prior art, reducing the resistance seen by the high velocity streams of cleaning fluid.
The vertical spray stems are formed to include a plurality of separate spray apertures and may be assembled in an adjustable configuration so that the separate jet streams may be directed to particular portions of a conditioner head that are more susceptible to carrying particulates. In vacuum-assisted conditioning systems, the cleaning fluids can be drawn through and/or around the abrasive, thus eliminating any interference with the static bath. Sequencing the vacuum can create additional flux and thus serve to pull a ‘slug’ of cleaning agent across, around and through the abrasive tooling.
It is an advantage of the present invention that the use of a plurality of high velocity jets of cleaning fluid results in creating targeted streams of cleaning fluid that impart cleaning energy on the conditioner surfaces, and result in atomized fluid ‘clouds/mist’ which condense on the conditioner head to keep broad surfaces moist between conditioning operations. Both the high velocity streams (for compacted residue and flat surfaces) and the atomized droplets (for non-working surface areas of the conditioner) are able to break the bond between the particulate matter and the conditioner head surfaces and force the particulate into the bath fluid (and ultimately drained or vacuumed away from the apparatus).
In yet another embodiment of the present invention, a gas may be dissolved in the cleaning fluid prior to entering the cleaning cup, where upon passing through the spray jets the gas is released and serves to further atomize the cleaning fluid and increase the efficiency of the cleaning operation. The gas itself may include an one or more components that are used to control the chemistry of the cleaning fluid.
Additionally, venturi systems can be incorporated into the spray outlet jet fixtures such that the bath is drawn down locally around the jets in the spray outlet by ‘drains’ connecting to the venturi-created pressure drop, further reducing the interference created by the static bath.
Other and further embodiments and features of the present invention will become apparent during the course of the following discussion and by reference to the accompanying drawings.
Referring now to the drawings,
In standard practice, conditioner head 5 is lowered into recessed portion 8 of cup 7 and immersed in the cleaning solution. The immersion is used to keep the abrasive conditioning disk moist between conditioning processes. Historically, it was presumed that as long as the conditioner head was not permitted to dry out, little if any slurry would remain on the conditioner head after submersion in the cleaning bath. It has since been discovered that the slurry may still adhere to the various surfaces of the conditioner head after cleaning, including the abrasive disk, resulting in a situation now referred to as “disk fouling”—where adhered slurry has been found to change the mechanical behavior of the conditioning disk during subsequent conditioning processes.
Similar to the various prior art arrangements, cleaning cup 10 includes a recessed area 12 that is filled with an appropriate cleaning solution (for example, deionized water) into which conditioner head 15 is lowered when not in use.
In contrast to prior art “static bath” arrangements, however, cleaning cup 10 of the present invention utilizes multiple, high velocity sprays of cleaning solutions to forcibly remove the unwanted slurry and other material from various surfaces of conditioner head 15. As shown in
Cleaning cup 10 is seen as also including a pair of vertical spray stems 14 and 16 in the form of restrictors, positioned as shown at the outer perimeter of cup 10. Spray stems 14 and 16 each comprise a plurality of individual jets that are used to direct targeted streams of high velocity water (or any other suitable cleaning fluid) against the side and top surfaces of conditioner head 15. A pair of deflectors 20, 22 (best seen in
It has been found that used slurry and other debris may cover various exposed areas of the end effector portion of conditioning arm 13 during the conditioning process. It is an advantage of the arrangement of the present invention that the high velocity sprays directed from stems 14 and 16 will loosen and remove any material from the outer surface of the conditioner head 15, as well as from the underlying abrasive conditioning disk and/or other conditioning system elements such as, for example, a vacuum cup. Upon impinging the surfaces of conditioner head 15, the high velocity streams will atomize and the energy from the collision will break the adhesion between the slurry residue and conditioner head outer surface. It has been found that there is a pressure-induced cohesive force and/or a charge affinity between adjacent slurry particles (agglomeration) that adheres the residue to the conditioner's surfaces. The energy from the high velocity streams has been found to be sufficient to break these bonds and liberate the residue from these surfaces.
In one embodiment, water knife 18 is formed of a suitable metal and is sufficiently recessed so that an overlying abrasive surface of conditioner head 15 (not shown in this view) will remain clear of knife 18. As discussed below in association with
As mentioned above, there may be arrangements where the conditioner head remains stationary while immersed in the cleaning fluid. In this case, a plurality of spray outlet sources may be included within recessed area 12 to provide sufficient coverage of the abrasive surface.
Spray stems 14 and 16, as described above, are formed as vertical, columnar restrictors that for directing high velocity streams of cleaning fluid toward the top and sides of the end effector portion of conditioning arm 13.
Preferably, jets 24 are formed so as to be adjustable, allowing for the user to control the direction of each individual stream so as to best clean the surface of a given conditioner head design.
As mentioned above, the geometry of spray outlet 18, in particular a water knife may be designed to create fluid motion within the static bath, creating turbulence that reduces the surface tension and reduces the force required by the upward-directed stream to break through the bath.
It is to be understood that the cleaning cup of the present invention may utilize various cleaning fluids, or combinations of fluids and/or gasses, in order to provide the most efficient cleaning operation. Indeed, the particular cleaning materials selected may be a function of the chemical composition of the polishing slurry, the material being removed from the wafer, the composition of the abrasive conditioning disk, etc.
This application claims the benefit of U.S. Provisional Application No. 60/899,976, filed Feb. 7, 2007.
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