Polishing apparatus

Information

  • Patent Grant
  • 6783445
  • Patent Number
    6,783,445
  • Date Filed
    Wednesday, September 26, 2001
    23 years ago
  • Date Issued
    Tuesday, August 31, 2004
    20 years ago
Abstract
A polishing apparatus comprises a polishing table having a polishing surface thereon, a top ring for pressing a workpiece to be polished against the polishing surface, and a dresser for dressing the polishing surface on the polishing table. The dresser comprises a dressing element provided on a surface of the dresser for dressing the polishing surface by sliding contact with the polishing surface, and an ejection nozzle provided on the surface of the dresser for ejecting a fluid supplied from a fluid source toward the polishing surface.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to a polishing apparatus for polishing a workpiece to be polished, and more particularly to a polishing apparatus for polishing a workpiece having a thin film formed thereon, such as a semiconductor wafer, to a flat mirror finish.




2. Description of the Related Art




As semiconductor devices have become more highly integrated in recent years, circuit interconnections have become finer and distances between these circuit interconnections become smaller. In case of photolithography which can form interconnections that are at most 0.5 μm wide, it is required that surfaces on which pattern images are to be focused by a stepper should be as flat as possible because a depth of focus of an optical system is relatively small. A polishing apparatus for performing chemical mechanical polishing (CMP) has been used for planarizing semiconductor wafer.




This type of polishing apparatus comprises, as shown in

FIG. 1

, a polishing table


302


having a polishing cloth (polishing pad)


300


attached thereon and constituting a polishing surface, and a top ring


304


for holding a substrate W as a workpiece to be polished, such as a semiconductor wafer, in such a manner that a surface to be polished faces the polishing cloth


300


. A semiconductor wafer W is polished by this polishing apparatus as follows: The polishing table


302


and the top ring


304


are independently rotated, and, while a polishing liquid is supplied from a polishing liquid nozzle


306


provided above the polishing table


302


, the semiconductor wafer W is pressed against the polishing cloth


300


on the polishing table


302


at a predetermined pressure by the top ring


304


. For example, a suspension of fine polishing particles of silica or the like in an alkali solution is used as the polishing liquid supplied from the polishing liquid nozzle


306


. Thus, the semiconductor wafer W is polished to a flat mirror finish by a combined effect of a chemical polishing effect attained by the alkali and a mechanical polishing effect attained by the polishing particles.




When the semiconductor wafer W is brought into contact with the polishing cloth


300


, and the polishing table


302


is rotated to perform polishing, a polishing liquid or ground-off particles of semiconductor material are attached to the polishing cloth


300


, resulting in a change in properties of the polishing cloth


300


and deterioration in polishing performance. Therefore, if an identical polishing cloth


300


is repeatedly used for polishing semiconductor wafers W, problems such as lowered polishing rate and uneven polishing are caused. In order to overcome such problems, a dresser


308


is provided in the polishing apparatus, and the polishing cloth


300


is dressed by the dresser


308


at a time of replacement of a semiconductor wafer W to be polished, for example. During a dressing process, while a dressing element attached to a lower surface of the dresser


308


is pressed against the polishing cloth


300


on the polishing table


302


, the polishing table


302


and the dresser


308


are independently rotated to remove the polishing liquid and the ground-off particles of the semiconductor material which are attached to the polishing surface and to flatten and dress the polishing surface in its entirety, whereby the polishing surface is regenerated. This dressing process is also referred to as a conditioning process.




During the dressing process, a portion of the dressing element brought into sliding contact with the polishing surface may come off the lower surface of the dresser and remain on the polishing surface in some cases. If the portion of the dressing element that has come off the lower surface of the dresser remains on the polishing surface, then a surface of a subsequent semiconductor wafer to be polished may be scratched by this portion of the dressing element.




For example, in the case of a diamond dresser, which comprises a dressing element constituted by particles such as diamond particles electrodeposited on a lower surface of a dresser, in order to reduce a number of diamond particles which come off the dressing element, it has been attempted to reduce a number of suspended particles present on the lower surface of the dressing element by performing an initial run-in or positioning the diamond particles at increased intervals. However, it is highly difficult to completely eliminate diamond particles from coming off the dressing element.




After a semiconductor wafer is polished by the top ring, polishing liquid used during the polishing process and ground-off particles of semiconductor material may possibly remain on the polishing surface of the polishing cloth. Since these remaining polishing liquid and ground-off particles tend to scratch a surface of a semiconductor wafer, it is necessary to remove them before a subsequent polishing process is performed.




SUMMARY OF THE INVENTION




It is therefore an object of the present invention to provide a polishing apparatus which can reliably remove a portion of a dressing element that has come off the dressing element, a polishing liquid, and ground-off particles of a workpiece material, with ease, and can increase quality of polishing of a workpiece.




In order to attain the above object, according to a first aspect of the present invention, there is provided a polishing apparatus comprising: a polishing table having a polishing surface thereon; a top ring for pressing a workpiece to be polished against the polishing surface; a dresser for dressing the polishing surface on the polishing table; a dressing element provided on a surface of the dresser for dressing the polishing surface by sliding contact with the polishing surface; and an ejection nozzle provided on the surface of the dresser for ejecting a fluid supplied from a fluid source toward the polishing surface.




With the above arrangement, a portion of the dressing element that has come off the dressing element during a dressing process, a polishing liquid, and ground-off particles of a workpiece material, are scattered toward an exterior of the dresser by fluid ejected from the ejection nozzle. Thus, the portion of the dressing element, the polishing liquid, and the ground-off particles, which remain on the polishing surface to cause a scratch, can effectively be removed from the polishing surface. Therefore, quality of polishing of a workpiece can be increased.




According to a second aspect of the present invention, there is provided a polishing apparatus comprising: a polishing table having a polishing surface thereon; a top ring for pressing a workpiece to be polished against the polishing surface; a dresser for dressing the polishing surface on the polishing table; a dressing element provided on a surface of the dresser for dressing the polishing surface by sliding contact with the polishing surface; and an ejection nozzle provided on the surface of the dresser for ejecting a mixture of a liquid supplied from a liquid source and a gas supplied from a gas source toward the polishing surface.




With the above arrangement, a polishing liquid and ground-off particles of a workpiece material which have fallen into recesses in the polishing surface can be blown away from the recesses by the gas contained in the mixture, and, further, can be washed away by the liquid. Thus, the polishing surface can effectively be cleaned.




Preferably, a dressing element is annularly disposed on the lower surface of the dresser, and the ejection nozzle is disposed inside of the annularly disposed dressing element.




According to a preferred aspect of the present invention, the dressing element has a fluid flow hole defined therethrough for flowing fluid from the fluid source to a lower surface of the dressing element, and a fluid ejection slot defined in a lower surface of the dressing element; and the fluid ejection slot is extended from the fluid flow hole to an outer circumferential edge of the dressing element.




With the above arrangement, fluid strongly flows out of the dresser under centrifugal forces due to rotation of the dresser. Therefore, a polishing surface can effectively be cleaned.




Preferably, the fluid ejection slot is extended toward an outer circumferential edge of the dresser. This arrangement can effectively increase a force of flow of fluid. Hence, an effect of cleaning of a polishing surface can be improved.




The above and other objects, features, and advantages of the present invention will be apparent from the following description when taken in conjunction with the accompanying drawings which illustrates preferred embodiments of the present invention by way of example.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a vertical cross-sectional view showing a conventional polishing apparatus;





FIG. 2

is a plan view showing a polishing apparatus according to an embodiment of the present invention;





FIG. 3

is a perspective view showing the polishing apparatus shown in

FIG. 2

;





FIG. 4

is a vertical cross-sectional view showing a polishing section of the polishing apparatus shown in

FIGS. 2 and 3

;





FIG. 5

is a schematic view showing a piping system of a dressing unit in the polishing section shown in

FIG. 4

;





FIG. 6

is a bottom view showing a dresser in the dressing unit shown in

FIG. 5

;





FIG. 7A

is an enlarged view showing a dressing element of the dresser shown in

FIG. 6

;





FIG. 7B

is a cross-sectional view taken along a line H—H of

FIG. 7A

; and





FIG. 8

is an enlarged view showing a dressing element according to another embodiment of the present invention.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




A polishing apparatus according to an embodiment of the present invention will be described below with reference to

FIGS. 2 through 7B

.





FIG. 2

is a plan view showing a polishing apparatus according to an embodiment of the present invention, and

FIG. 3

is a perspective view showing the polishing apparatus shown in FIG.


2


. As shown in

FIGS. 2 and 3

, in the polishing apparatus according to this embodiment, a pair of polishing sections


1




a


,


1




b


is disposed on one side of a space on a floor having a rectangular shape, so as to laterally face each other. A pair of load/unload units for placing thereon cassettes


2




a


,


2




b


for accommodating semiconductor wafers therein is disposed on another side of the space. Two transfer robots


4




a


,


4




b


for transferring a semiconductor wafer are disposed on a line connecting the polishing sections


1




a


,


1




b


to the load/unload units to constitute a transfer line. Two inverters


5


,


6


are disposed on each side of the transfer line, and two sets of cleaning units


7




a


,


7




b


and


8




a


,


8




b


are disposed on each side of the transfer line. The inverter


5


is interposed between the cleaning units


7




a


and


8




a


, and the inverter


6


is interposed between the cleaning units


7




b


and


8




b.






The two polishing sections


1




a


,


1




b


have basically identical specifications relative to each other, and are positioned symmetrically with respect to the transfer line. Each of the polishing sections


1




a


,


1




b


comprises a polishing table


11


having a polishing cloth attached to an upper surface thereof, a top ring unit


12


for holding a semiconductor wafer W, as a workpiece to be polished, by vacuum suction and pressing the semiconductor wafer W against the polishing table


11


to polish the semiconductor wafer W, and a dressing unit


13


for dressing the polishing cloth on the polishing table


11


. Pushers


14


for receiving a semiconductor wafer W from the top ring unit


12


and transferring the semiconductor wafer W to the top ring unit


12


are provided near the transfer line in each of the polishing sections


1




a


,


1




b.






A polishing surface is constituted by an upper surface of the polishing cloth. The polishing surface may be constituted by a fixed abrasive pad or a grinding stone. The polishing cloth can be made of elastic polyurethane foam or a non-woven fabric. The grinding stone comprises abrasive particles fixed by a binder of resin or the like. One example of fixed abrasive pads comprises an upper layer of abrasive particles fixed by a binder and a lower layer of an elastic pad attached to the upper layer. Alternatively, the fixed abrasive pad comprises abrasive particles fixed by an elastic binder such as polyurethane.




Each of the transfer robots


4




a


,


4




b


has an articulated arm which is bendable and extendable within a horizontal plane, and upper and lower holding portions which are separately used as a dry finger and a wet finger, respectively. Since two robots are used in this embodiment, a first robot


4




a


is basically responsible for a region from the inverters


5


,


6


to the cassettes


2




a


,


2




b


, and a second robot


4




b


is basically responsible for a region from the inverters


5


,


6


to the polishing sections


1




a


,


1




b.






The inverters


5


,


6


serve to turn over a semiconductor wafer W, and are disposed at positions that can be reached by the hands of the transfer robots


4




a


,


4




b


. In this embodiment, the two inverters


5


,


6


are separately utilized as a device for handling a dry semiconductor wafer and a device for handling a wet semiconductor wafer, respectively.




Each of the cleaning units


7




a


,


7




b


,


8




a


and


8




b


may be of any type. For example, the cleaning units


7




a


,


7




b


near the polishing sections


1




a


,


1




b


are of a type that wipes both sides of a semiconductor wafer with a roller equipped with a sponge, and the cleaning units


8




a


,


8




b


near the cassettes


2




a


,


2




b


are of a type that holds an edge of a semiconductor wafer and rotates the semiconductor wafer within a horizontal plane while supplying a cleaning liquid to the semiconductor wafer. The cleaning units


8




a


,


8




b


also serve as a drier for centrifugally drying a semiconductor wafer. The cleaning units


7




a


,


7




b


can perform a primary cleaning process of a semiconductor wafer, and the cleaning units


8




a


,


8




b


can perform a secondary cleaning process of a semiconductor wafer after the primary cleaning process.





FIG. 4

is a vertical cross-sectional view showing a main part of the polishing section la shown in

FIGS. 2 and 3

. Only the polishing section


1




a


will be described below. However, the following description can be applied to the polishing section


1




b.






As shown in

FIG. 4

, polishing cloth


10


on the polishing table


11


has its upper surface serving as a polishing surface held in sliding contact with a semiconductor wafer W as a workpiece to be polished. The polishing table


11


is coupled to a motor (not shown) disposed below the polishing table


11


via a table shaft


11




a


, so that the polishing table


11


is rotatable about the table shaft


11




a


in a direction indicated by arrow C in FIG.


4


.




A polishing liquid supply nozzle


15


and a water supply nozzle


16


are disposed above the polishing table


11


. A polishing liquid for use during polishing is supplied onto the polishing cloth


10


from the polishing liquid supply nozzle


15


. A dressing liquid for use during dressing, e.g., water, is supplied onto the polishing cloth


10


from the water supply nozzle


16


. The polishing table


11


is surrounded by a frame


17


for recovering polishing liquid and water that have been supplied onto the polishing cloth


10


. A tub


17




a


for collecting and draining the polishing liquid and the water is provided at a bottom of the frame


17


.




The top ring unit


12


comprises a rotatable spindle


20


, a swing arm


21


coupled to an upper end of the spindle


20


, a top ring shaft


22


extended downwardly from a free end of the swing arm


21


, and a substantially disk-shaped top ring


23


coupled to a lower end of the top ring shaft


22


. When the swing arm


21


is swung by rotation of the spindle


20


, the top ring


23


is horizontally moved, and thus can be reciprocated between the pusher


14


and a polishing position on the polishing cloth


10


, as indicated by arrow A in FIG.


2


. Further, the top ring


23


is coupled via the top ring shaft


22


to a motor (rotating mechanism) and a lifting/lowering cylinder (both not shown) provided within the swing arm


21


, so that the top ring


23


is vertically movable, as indicated by arrow D in

FIG. 4

, and is rotatable about an axis of the top ring shaft


22


, as indicated by arrow E in

FIG. 4. A

semiconductor wafer W as a workpiece to be polished is attracted to and held on a lower surface of the top ring


23


by vacuum suction or the like. Thus, the top ring


23


can rotate and press the semiconductor wafer W held on its lower surface against the polishing cloth


10


at a desired pressure.




The dressing unit


13


serves to regenerate a surface of the polishing cloth


10


that has been deteriorated as a result of a polishing operation, and is disposed at a position opposite to the top ring unit


12


with respect to a center of the polishing table


11


. The dressing unit


13


comprises a rotatable spindle


30


, a swing arm


31


coupled to an upper end of the spindle


30


, a dresser shaft


32


extended downwardly from a free end of the swing arm


31


, and a substantially disk-shaped dresser


33


coupled to a lower end of the dresser shaft


32


, similar to the case of the top ring unit


12


. When the swing arm


31


is swung by rotation of the spindle


30


, the dresser


33


is horizontally moved, and thus can be reciprocated between a dressing position on the polishing cloth


10


and a standby position which is positioned outside of the polishing table


11


, as indicated by arrow B in FIG.


2


. Further, the dresser


33


is coupled via the dresser shaft


32


to a motor (rotating mechanism) and a lifting/lowering cylinder (both not shown) provided within the swing arm


31


, so that the dresser


33


is vertically movable, as indicated by arrow F in

FIG. 4

, and is rotatable about the dresser shaft


32


, as indicated by arrow G in FIG.


4


.





FIG. 5

is a schematic view showing a piping system of the dressing unit


13


in the polishing section


1




a


shown in

FIG. 4

, and

FIG. 6

is a bottom view showing the dresser


33


shown in FIG.


4


. In

FIG. 5

, a portion of the dressing unit


13


is shown in cross section. As shown in

FIGS. 5 and 6

, the dresser


33


has a plurality of dressing elements


34


mounted on a lower surface of the dresser


33


for dressing the polishing cloth


10


by sliding contact with the polishing cloth


10


. In this embodiment, each of the dressing elements


34


comprises a diamond pellet made of diamond particles electrodeposited on a disk, and a plurality of dressing elements


34


are mounted on the lower surface of the dresser


33


. As shown in

FIG. 6

, the dressing elements


34


are positioned along a circumferential direction of the dresser


33


at predetermined intervals, and thus annularly disposed on the lower surface of the dresser


33


as a whole. The dresser


33


rotates and presses the dressing elements


34


against the polishing cloth


10


at a desired pressure to dress the polishing surface of the polishing cloth


10


. The dressing elements


34


may comprise a brush which has elongated bristles such as nylon.




The dresser


33


has a plurality of ejection nozzles


35


provided on its lower surface for ejecting a liquid in the form of a mixture of a nitrogen gas and pure water as a cleaning liquid, toward a polishing surface of the polishing cloth


10


. As shown in

FIGS. 5 and 6

, the ejection nozzles


35


are disposed in an area surrounded by the annularly disposed dressing elements


34


, i.e., inside of the dressing elements


34


. The ejection nozzles


35


are radially positioned around a center of the dresser


33


. Each of the ejection nozzles


35


is a nozzle directed toward an outer circumferential edge of the dresser


33


so as to eject liquid toward the outer circumferential edge of the dresser


33


.




As shown in

FIG. 5

, nitrogen gas from a nitrogen gas source (gas source)


40


and pure water from a pure water source (fluid source)


50


are supplied to the ejection nozzles


35


via a gas passage


41


and a liquid passage


51


, respectively. Pressure of nitrogen gas from the nitrogen gas source


40


is regulated by a regulator


42


. The nitrogen gas is supplied to the ejection nozzles


35


via an air-operated valve


43


and a rotary joint


60


. Pressure of pure water from the pure water source


50


is regulated by a regulator


52


. The pure water is supplied to the ejection nozzles


35


via an air-operated valve


53


and the rotary joint


60


. The gas passage


41


and the liquid passage


51


are joined to each other to mix the pure water and the nitrogen gas at an upstream side of the ejection nozzles


35


. A mixture of the pure water and the nitrogen gas flows into a passage


36


formed in the dresser


33


and is then supplied to the ejection nozzles


35


via the passage


36


.




The mixture of the nitrogen gas and the pure water is brought in as liquid fine particles, solid fine particles as a result of solidification of liquid, or gas as a result of vaporization of liquid. To bring the mixture into these states is referred to as atomization. An atomized mixture is ejected from the ejection nozzles


35


toward the polishing table


11


. Which state of the mixed liquid to be ejected, i.e., the liquid fine particles, the solid fine particles, or gas, is determined, for example, depending on pressure or temperature of the nitrogen gas and/or the pure water, or a shape of nozzles. Therefore, the state of the liquid to be ejected can be varied, for example, by properly varying pressure or temperature of the nitrogen gas and/or the pure water via a regulator or the like, or by properly varying a shape of nozzles.





FIG. 7A

is an enlarged view showing one of the dressing elements


34


shown in

FIG. 6

, and

FIG. 7B

is a cross-sectional view taken along a line of H—H in FIG.


7


A. Each of the dressing elements


34


has a large number of diamond particles electrodeposited on a lower surface thereof. As shown in

FIGS. 7A and 7B

, the dressing element


34


has a vertical fluid flow hole


34




a


defined therethrough, and a plurality of fluid ejection slots


34




b


defined in the lower surface thereof. In this embodiment, as shown in

FIG. 7A

, the fluid ejection slots


34




b


are extended from a lower end of the fluid flow hole


34




a


toward an outer circumferential edge


33




a


of the dresser


33


and reach an outer circumferential edge of the dressing element


34


. An upper end of the fluid flow hole


34




a


communicates with the passage


36


in the dresser


33


. The mixture supplied from the passage


36


flows through the fluid flow hole


34




a


and the fluid ejection slots


34




b


and then flows out of the dresser


33


.




Operation of the polishing apparatus thus constructed for polishing a semiconductor wafer W and dressing polishing cloth


10


will be described below.




When a polishing process of a semiconductor wafer W is performed in the polishing section


1




a


, the top ring


23


and the polishing table


11


are independently rotated, and a semiconductor wafer W held on the top ring


23


and the polishing table


11


are relatively moved to press the semiconductor wafer W held on a lower surface of the top ring


23


against the polishing cloth


10


on the polishing table


11


. At this time, a polishing liquid is supplied from the polishing liquid supply nozzle


15


onto the upper surface of the polishing cloth


10


. For example, a suspension of fine polishing particles of silica or the like in an alkali solution is used as the polishing liquid. Thus, the semiconductor wafer W is polished by a combined effect of a chemical polishing effect attained by the alkali and a mechanical polishing effect attained by the polishing particles. The polishing liquid used during the polishing process is scattered to an outside of the polishing table


11


by centrifugal force due to rotation of the polishing table


11


, and is recovered in the tub


17




a


provided at the lower portion of the frame


17


.




The polishing process of the semiconductor wafer W is completed when the semiconductor wafer W is polished to a certain thickness. At this time, properties of the polishing cloth


10


are changed due to the polishing process, so that polishing performance for a subsequent polishing process is deteriorated. Therefore, the polishing cloth


10


is dressed by the dressing unit


13


. During a dressing process, the dresser


33


and the polishing table


11


are independently rotated, and the dressing elements


34


mounted on the dresser


33


are pressed against the polishing cloth


10


at a predetermined pressure. At the same time that the dressing elements


34


are brought into contact with the polishing cloth


10


or before the dressing elements


34


are brought into contact with the polishing cloth


10


, water is supplied from the water supply nozzle


16


onto the polishing cloth


10


to wash away used polishing liquid that remains on the polishing cloth


10


.




While the polishing cloth


10


is being dressed, the regulators


42


,


52


and the air-operated valves


43


,


53


are controlled to supply nitrogen gas and pure water at predetermined pressures and temperatures to the ejection nozzles


35


in the dresser


33


for ejecting a mixture of the nitrogen gas and the pure water to the polishing cloth


10


. It is preferable to supply the nitrogen gas under pressures ranging from 0.01 MPa to 0.7 MPa, and to supply the pure water under pressures ranging from 0.1 MPa to 0.3 MPa. The mixture is ejected in an atomized state onto the polishing cloth


10


, scattering a portion of the dressing elements


34


that has come off the dressing elements


34


in the dressing process toward the outside of the dresser


33


. At the same time, this ejected mixture scatters polishing liquid and ground-off particles of the semiconductor material remaining on the polishing cloth


10


toward an exterior of dresser


33


. Particularly, polishing liquid and ground-off particles that have fallen into recesses in the polishing cloth


10


can be blown away from the recesses by gas contained in the mixture, and, further, can be washed away by cleaning liquid (pure water). Thus, the polishing liquid and the ground-off particles, which remain on the polishing cloth


10


to cause a scratch, can effectively be removed from the polishing cloth


10


.




The mixture simultaneously flows from the passage


36


in the dresser


33


through the fluid flow hole


34




a


and the fluid ejection slots


34




b


, out of the dresser


33


. Since the dresser


33


is rotated at this time, the mixture is forced to flow out of the dresser


33


under centrifugal forces. Therefore, the polishing cloth


10


is effectively cleaned. Particularly, since the fluid ejection slots


34




b


are extended from the fluid flow hole


34




a


toward the outer circumferential edge


33




a


of the dresser


33


, as shown in

FIG. 7A

, the mixture strongly flows out of the dresser


33


. Hence, an effect of cleaning of the polishing cloth


10


can be improved.




Water supplied onto the polishing cloth


10


and the mixture ejected from the ejection nozzles


35


onto the polishing cloth


10


are scattered from the polishing table


11


under centrifugal forces due to rotation of the polishing table


11


, and are collected by the tub


17




a


in the frame


17


. After the dressing process, the dresser


33


is returned to a standby position by the swing arm


31


, and cleaned by a dresser cleaning unit


18


(see

FIG. 2

) disposed at the standby position.




In this embodiment, nitrogen gas is supplied from the gas source


40


to the ejection nozzles


35


, and pure water is supplied as the cleaning liquid from the fluid source


50


to the ejection nozzles


35


. However, only a liquid (cleaning liquid) may be supplied from the fluid source


50


to the ejection nozzles


35


without a gas being supplied from the gas source


40


. In this case, the regulator


52


in the liquid passage


51


may be controlled to supply liquid (pure water) at a high pressure to the ejection nozzles


35


for removing polishing liquid and ground-off particles of semiconductor material from recesses in the polishing cloth


10


.




The ejection nozzles


35


in the lower surface of the dresser


33


are not limited to the illustrated number and layout. The fluid flow hole


34




a


and the fluid ejection slots


34




b


which are defined in the dressing elements


34


are not limited to the illustrated positions and shapes. For example, as shown in

FIG. 8

, the dressing element


34


may have a fluid flow hole


34




a


defined at a central portion thereof and fluid ejection slots


34




b


defined therein at 90° intervals and extended radially outwardly from the fluid flow hole


34




a


. Further, in this embodiment, the dressing element


34


of the dresser


33


comprises a diamond pellet. However, each of the dressing elements


34


may comprise a brush.




Although certain preferred embodiments of the present invention have been shown and described in detail, it should be understood that various changes and modifications may be made therein without departing from the scope of the appended claims.



Claims
  • 1. A polishing apparatus comprising:a polishing table having a polishing surface thereon; a top ring for pressing a workpiece to be polished against said polishing surface; and a dresser for dressing said polishing surface on the polishing table, said dresser including (i) a shaft to rotate said dresser about an axis passing through said dresser, (ii) a dressing element provided on a surface of said dresser for dressing said polishing surface by sliding contact with said polishing surface, and (iii) an ejection nozzle provided on the surface of said dresser for ejecting a fluid toward said polishing surface, said ejection nozzle being directed toward an outer circumferential edge of said dresser so as to eject the fluid toward the outer circumferential edge of said dresser, wherein said dressing element has a fluid flow hole defined therethrough for flowing the fluid to a lower surface of said dressing element, and a fluid ejection slot defined in the lower surface of said dressing element, and wherein said fluid ejection slot is extended from said fluid flow hole to an outer circumferential edge of said dressing element.
  • 2. The polishing apparatus according to claim 1, wherein said dressing element is annularly disposed on a lower surface of said dresser, and said ejection nozzle is disposed inside of said dressing element.
  • 3. The polishing apparatus according to claim 1, wherein said fluid ejection slot is extended toward the outer circumferential edge of said dresser.
  • 4. The polishing apparatus according to claim 1, wherein the fluid comprises a mixture of a fluid supplied from a fluid source and a gas supplied from a gas source.
  • 5. The polishing apparatus according to claim 4, wherein said dressing element is annularly disposed on a lower surface of said dresser, and said ejection nozzle is disposed inside of said dressing element.
  • 6. The polishing apparatus according to claim 4, wherein said fluid rejection slot is extended toward the outer circumferential edge of said dresser.
  • 7. The polishing apparatus according to claim 4, wherein said dresser further includes a rotary joint provided in a passage for supplying the mixture of the fluid and the gas to said ejection nozzle.
  • 8. The polishing apparatus according to claim 1, wherein said dresser further includes a rotary joint provided in a passage for supplying the fluid to said ejection nozzle.
  • 9. A dresser for dressing a polishing surface on a polishing table, said dresser comprising:a shaft to rotate said dresser about an axis passing through said dresser; a dressing element provided on a surface of said dresser for dressing said polishing surface by sliding contact with the polishing surface; and an ejection nozzle provided on the surface of said dresser for ejecting a fluid toward the polishing surface, said ejection nozzle being directed toward an outer circumferential edge of said dresser so as to eject the fluid toward the outer circumferential edge of said dresser, wherein said dressing element has a fluid flow hole defined therethrough for flowing the fluid to a lower surface of said dressing element, and a fluid ejection slot defined in the lower surface of said dressing element, and wherein said fluid ejection slot is extended from said fluid flow hole to an outer circumferential edge of said dressing element.
  • 10. The dresser according to claim 9, wherein said dressing element is annularly disposed on a lower surface of said dresser, and said ejection nozzle is disposed inside of said dressing element.
  • 11. The dresser according to claim 9, wherein said fluid ejection slot is extended toward the outer circumferential edge of said dresser.
  • 12. The dresser according to claim 9, wherein the fluid comprises a mixture of a fluid supplied from a fluid source and a gas supplied from a gas source.
  • 13. The dresser according to claim 12, wherein said dressing element is annularly disposed on a lower surface of said dresser, and said ejection nozzle is disposed inside of said dressing element.
  • 14. The dresser according to claim 12, wherein said fluid ejection slot is extended toward the outer circumferential edge of said dresser.
  • 15. The dresser according to claim 12, further comprising a rotary joint provided in a passage for supplying the mixture of the fluid and the gas to said ejection nozzle.
  • 16. The dresser according to claim 9, further comprising a rotary joint provided in a passage for supplying the fluid to said ejection nozzle.
Priority Claims (1)
Number Date Country Kind
2000-294666 Sep 2000 JP
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Entry
Tatsuo Inoue et al., U.S. patent application Ser. No. 09/790,976, filed Feb. 23, 2001.