Patent Grant
8029333
This invention relates to a device for polishing the peripheral edge part (including the notch and the beveled part) of a semiconductor wafer.
The peripheral edge part of a semiconductor wafer is conventionally polished by independently using a device for polishing the notch part (as disclosed in Japanese Patent Publication Tokkai 9-85599) and another device for polishing the beveled part (as disclosed in Japanese Patent Publications Tokkai 7-164301 and 8-174399). The polishing of the peripheral part is carried out by a so-called wet method whereby a polishing liquid in a slurry form obtained by dispersing abrading particles in water or a water-based reactive liquid is supplied to the target part to be polished (such as the notch and/or the beveled part) together with cooling water while a tape made of a woven or non-woven cloth or a foamed body or a tape having a polishing layer with abrading particles affixed by an adhesive formed on the surface of a plastic material is pressed onto the target part and caused to run.
Such conventional methods have problems because the notch and the beveled part of a semiconductor wafer are polished independently such that it takes too long to transport the wafer between these two devices and this requires a large space for the equipment. There is also the problem of the semiconductor wafer becoming dry while being transported, adversely affecting the yield of device wafers.
The positioning of a semiconductor wafer on the wafer stage in each polishing device is carried out by means of a pair of chuck handles of a robot for transporting wafers but since a plurality of cylinders are used for improved accuracy in the positioning, a large space is required for the equipment. Since air cylinders are used for the purpose, furthermore, an error on the order of 0.5 mm arises in the positioning. There is still another problem that an excessive grasping force is applied on the peripheral edge of the wafer and tends to damage the edge portion of the wafer.
The semiconductor wafer is adsorbed to the wafer stage by vacuum. When this semiconductor wafer is removed from the wafer stage, the wafer is released from this condition of vacuum adsorption as the wafer is grasped on its peripheral parts by the pair of chuck handles of the robot and lifted up. This means that a large releasing force is required for removing the semiconductor wafer from the wafer stage and this must be exerted instantaneously on the semiconductor wafer. This gives rise to the problem of deforming or damaging the semiconductor wafer.
According to prior art technologies, a polishing tape is supplied from a supply roller during the polishing process by changing the torque value of a motor for the supply of the tape according to the outer diameter of the tape (that is, the amount of the tape still remaining on the supply roll) such that the tension of the tape pressed onto the target portion to be polished can be adjusted. Since the outer diameter of the tape is determined by the presence or absence of light from a light emitter received by a plurality (usually eight) of sensors of a light receiving part arranged at the side of the tape supply roll, the torque value of the motor changes in a stepwise manner, giving rise to the problem of the tension in the tape not being constant.
It is therefore an object of this invention, which relates to the processing of the peripheral part a semiconductor wafer, to provide a device for polishing the notch and the beveled part of a semiconductor wafer efficiently within a single device.
It is another object of this invention to provide such a device with which the polishing time can be shortened and the space required for the apparatus can be reduced.
It is a third object of this invention to provide such a device capable of positioning a semiconductor wafer accurately on a wafer stage.
It is a fourth object of this invention to provide such a device capable of easily removing a semiconductor wafer supported by adsorption on the wafer stage.
It is a fifth object of this invention to provide such a device capable of maintaining the tension in the tape constant independent of the outer diameter of the tape (or its remaining amount on the supply roll) on the polishing head.
A device according to this invention with which the objects described above can be accomplished is for polishing the peripheral edge part of a semiconductor wafer and comprises a wafer stage having a surface for holding the semiconductor wafer, a wafer stage unit including a stage rotating part for rotating the wafer stage and a reciprocating motion part for causing the wafer stage to undergo a rotary reciprocating motion within the same plane as the surface of the wafer stage, a stage moving part for moving the wafer stage parallel to the surface, and two or more polishing parts for polishing the peripheral edge part of the semiconductor wafer being held by the wafer stage.
These two or more polishing parts include a notch polishing part for polishing a notch on the semiconductor wafer held by the wafer stage and a bevel polishing part for polishing beveled part of the semiconductor wafer held by the wafer stage.
The device of the invention further comprises a housing that contains the wafer stage unit, the polishing parts and the stage moving part and has a side surface with an opening which can be opened and closed. The housing includes two chambers partitioned by a partition plate, one of the chambers containing the wafer stage unit and the polishing parts, and the other of the chambers containing the stage moving part.
The device of the invention further comprises a dryness preventing part for supplying pure water to the semiconductor wafer held by the wafer stage.
The device of the invention further comprises a chuck assembly for receiving the semiconductor wafer transported into the housing, placing the semiconductor wafer on the wafer stage and delivering the semiconductor wafer on the wafer stage to a wafer transporting part. The chuck assembly includes a first chuck hand having two or more knobs, a second chuck hand having two or more knobs, a chuck opening part for opening and closing the first chuck hand and the second chuck hand, and a chuck moving part for causing the first chuck hand and the second check hand to undergo a reciprocating motion perpendicularly to the surface of the wafer stage, wherein the knobs contact peripheral parts of the semiconductor wafer when the first chuck hand and the second chuck hand are closed such that the semiconductor wafer becomes grasped by the first chuck hand and the second chuck hand.
The chuck opening part comprises a ball screw engaging with at least one of the first and second chuck hands and a servo motor for driving the ball screw wherein the first and second chuck hands open and close as the servo motor is activated.
The device of this invention further comprises a sensor assembly having a notch detecting part for detecting the position of a notch on semiconductor wafer being held on the wafer stage by suction. The notch detecting part includes an optical sensor having a light emitter and a light receiver arranged such that the notch on the semiconductor wafer held by the wafer stage by suction passes between the light emitter and the light receiver, the optical sensor serving to detect the position of the notch by rotating the semiconductor wafer.
Preferably, the sensor assembly includes three optical sensors which are first optical sensor, second optical sensor and third optical sensor, the first optical sensor being adapted to detect the position of the notch when the wafer stage is rotating at a rotational speed within a first range, the second optical sensor being adapted to detect the position of the notch when the wafer stage is rotating at a rotational speed within a second range that is slower than the first range, and the third optical sensor being adapted to detect the position of the notch when the wafer stage is rotating at a rotational speed within a third range that is slower than the second range.
The sensor assembly further includes a displacement detecting part for detecting positional displacement in radial direction of the semiconductor wafer held by the wafer stage by suction, the displacement detecting part comprising an optical sensor having a light emitter and a light receiver arranged such that the peripheral edge of the semiconductor wafer held by the wafer stage by suction passes between the light emitter and the light receiver, the optical sensor serving to detect changes in the quantity of light received by the light receiver and to thereby detect a radial displacement of the position of the semiconductor wafer held by the wafer stage by suction.
Preferably, the third sensor is arranged such that the peripheral edge including the notch of the semiconductor wafer held by the wafer stage by suction passes between the light emitter and the light receiver, the third optical sensor serving to detect changes in the quantity of light received by the light receiver thereof and to thereby detect a radial displacement of the position of the semiconductor wafer held by the wafer stage by suction and to detect the position of the notch of the semiconductor wafer when the wafer stage is rotating at a rotary speed within the third range.
The sensor assembly further comprises a waterproofing part for waterproofing the sensor assembly.
The notch polishing part comprises a notch polishing head having a first roller and a second roller arranged parallel to each other with an interval in between and a tape supplying part including a supply roll having a tape wound therearound, a take-up roller for taking up the tape from the supply roll through the first and second rollers and a driving part for driving the take-up roller for taking up the tape, wherein the tape is adapted to be pressed against the notch while passing between the first roller and the second roller to thereby polish the notch.
The tape comprises a tape-shaped base film of a plastic material having a polishing layer with abrading particles fastened by a resin binder.
The notch polishing part further includes a mechanism for causing the notch polishing head to undergo a reciprocating motion perpendicularly to the semiconductor wafer while the tape is pressed against the notch.
The notch polishing part further includes another mechanism for causing the notch polishing head to undergo a rotary reciprocating motion around the notch while the tape is pressed against the notch such that both front and back surface sides of the notch are polished.
Preferably, the notch polishing part further includes a diameter detecting part for detecting the outer diameter of the tape remaining wound around the supply roll.
The bevel polishing part comprises a bevel polishing head having a cylinder with a contact pad attached to an end and a tape supplying part having a supply roll having a tape wound therearound, a take-up roller for winding up the tape from the supply roll through the contact pad, and a driving part for driving the take-up roller for winding up the tape, wherein the tape is pressed against the beveled part while passing on the contact pad and thereby polishes the beveled part.
The tape comprises a tape-shaped base film of a plastic material having a polishing layer with abrading particles fastened by a resin binder.
The bevel polishing part further includes a mechanism for causing the bevel polishing head to undergo a rotary reciprocating motion around the semiconductor wafer while the tape is pressed against the beveled part such that both front and back surface sides of the beveled part are polished.
The bevel polishing part further includes a diameter detecting part for detecting the outer diameter of the tape remaining wound around the supply roll.
The bevel polishing part further includes a displacement detecting part for detecting displacement of the semiconductor wafer while the beveled part is being polished, the displacement detecting part comprising a displacement sensor for detecting change in stretching and shrinking of the cylinder serving to compress the tape to the beveled part through the contact pad while the semiconductor wafer is being polished.
The device of this invention further comprises a cleaning part for maintaining the interior of the housing clean, the cleaning part comprising an air inlet through an upper surface of the housing, an air discharge outlet through a lower side surface of the housing and an external pump connected to the air discharge outlet, the air inlet and the air discharge outlet being arranged such that air flows in through the air inlet and flows inside the housing along side surfaces thereof.
The device of this invention further comprises a structure for waterproofing the other chamber.
Preferably, the partition plate of the device of this invention has an opening, wherein the stage rotating part comprises a first shaft attached to the center on the back of the wafer stage, a support member rotatably attached to the first shaft and a first motor for rotating the first shaft, wherein the reciprocating motion part comprises a second shaft that is affixed to the support member of the wafer stage at a position offset from the center of the wafer stage by approximately the distance of one half of the radius of the semiconductor wafer through the opening through said partition plate and a second motor for rotating the second shaft, the second shaft being rotatably attached to a shaft table that is hollow and cylindrical, the shaft table having a lower surface affixed to a support plate below the partition plate and an upper surface supporting the support member by contacting the lower surface of the support member and the second motor being affixed to the support member, and wherein the device further comprises a hollow semi-spherical waterproofing cover having an upper affixed in a liquid-tight manner to an upper part of the shaft table and a lower part affixed in a liquid-tight manner around the opening through the partition plate, the waterproofing cover being made of an elastic material.
Preferably, the waterproofing cover is of a double structure having an inner cover and an outer cover, said device further comprising an air supplying part for supplying compressed air into a space between said inner cover and said outer cover.
A method of this invention with which the objects described above can be accomplished is for polishing peripheral edge part of a semiconductor wafer and comprises holding step of holding the semiconductor wafer by a wafer stage by suction and polishing step of polishing the peripheral edge part of the semiconductor wafer supported by the wafer stage by suction by two or more polishing parts. The polishing step comprises moving the wafer stage supporting the semiconductor wafer sequentially to each of the two or more polishing parts and causing each of the polishing parts to polish the peripheral part of the semiconductor wafer.
The method of this invention further comprises dryness preventing step of supplying pure water to the semiconductor wafer supported by the wafer stage while the semiconductor wafer is being transported between the two or more polishing parts.
The two or more polishing parts include a notch polishing part for polishing a notch on the semiconductor wafer and a bevel polishing part for polishing a beveled part of the semiconductor wafer.
Since this invention is constituted as above, the following effects are conducted.
Since a semiconductor wafer is transported between a notch polishing head and a bevel polishing head by simply moving a wafer stage by operation of a stage moving part, not only a notch and a beveled part of a semiconductor wafer can be polished efficiently within a single device, but also the polishing time can be shortened and the space required for the apparatus can be reduced.
A semiconductor wafer can be positioned accurately on a wafer stage by the notch detecting part and the displacement detecting part.
According to this invention, while a semiconductor wafer supported by adsorption on the wafer stage is grasped and lifted up by the chuck hands, this wafer can be easily released from the suction force towards the wafer stage by stopping the operation of the vacuum pump when the wafer has been lifted up just a little (0.5 mm-1.0 mm).
Since an optical sensor continuously detects the outer diameter of the tape (or its remaining amount on the supply roll), the tension in the tape can be maintained in constant.
Components of a driving system (the stage moving part) are covered with the waterproof cover made of an elastic material, and thereby the driving system in the device can be protected against water.
A device according to this invention is for polishing the peripheral edge part of a semiconductor wafer (inclusive of the notch and the beveled part).
As shown in
The wafer W may be roughly classified either as a straight type or a round type, depending on its cross-sectional shape. A semiconductor wafer of a straight type has a polygonal sectional shape as shown in
Throughout herein, expression “beveled part” will be used, in the case of a wafer W of a straight type shown in
There is a housing 11, which is divided into two spaces (an upper chamber 15 and a lower chamber 16) by means of a partition plate 14, the upper chamber 15 containing the wafer stage unit 20, the notch polishing part 40 and the bevel polishing part 50 and the lower chamber 16 containing the stage moving part 30.
The housing 11 is provided with an opening 12 on the side surface of its upper chamber 15. This opening 12 can be opened and closed by means of a shutter 13 adapted to be driven by a cylinder (not shown). The wafer W is brought into and taken out of the housing 11 through this opening 12. A wafer transporting part of a known kind such as a robot hand (as shown by numeral 13′ in
The device 10 of this invention further comprises a wafer chuck assembly 80 for placing the wafer W brought inside the housing 11 onto the wafer stage 23 and picking up the wafer W placed on the wafer stage 23 away from the wafer stage 23.
As shown in
As shown in
As shown in
As shown in
As shown in
Grooves 26 and 26′ connected to the suction hole 25 are formed on the upper surface of the pad 24. Preferably, the pad 24 is formed with concentric circular grooves 26 and a plurality of radial grooves 26′ that connect the circular grooves 26 and these grooves 26 and 26′ are connected to the vacuum pump referred to above. As the wafer W is placed on the pad 24, these grooves 26 and 26′ are sealed by the lower surface of the wafer W in an airtight manner. Thus, if the vacuum pump is activated, the wafer comes to be supported from its bottom side by the pad 24 without deforming (bending).
The wafer W, thus clasped by the first and second chuck hands 81 and 82, is placed on the pad 24 on the wafer stage 23 by the chuck moving part 85. As these chuck hands 81 and 82 are opened by the chuck hand opening part 84, the vacuum pump is simultaneously activated and the pressure in the space on the backside of the wafer W (or the interior of the grooves 26 and 26′ formed on the upper surface of the pad 24) is reduced, causing it to be pressed towards the pad 24 and to sink somewhat into it. This is how the wafer W is securely adsorbed to the wafer stage 23 and supported by it.
The wafer W thus adsorbed to and supported by the wafer stage 23 is grasped by the first and second chuck hands 81 and 82 and then lifted up by the chuck moving part 85. When it has floated up a little (say, 0.5 mm-1.0 mm), the vacuum pump is stopped and the vacuum suction is stopped. In this manner, there is no instantaneously large force applied to the wafer W when it is removed from the condition of being adsorbed to the wafer stage 23. In other words, the wafer W can be removed from the wafer stage 23 without deforming it or damaging it.
As shown in
The reciprocating motion part is for causing the wafer stage 23 to undergo a rotary reciprocating motion in the same plane as the surface of the wafer stage 23 and comprises a shaft 31 which penetrates an opening 17 through the partition plate 14 of the housing 11 at a position offset from the rotary shaft Cs of the wafer stage 23 approximately by the length of the radius of the wafer W and is affixed to the lower surface of the support member 22 of the unit main body 21 and a motor m2 connected to this shaft 31 through a pulley p2 and a belt b2. The shaft 31 is rotatably attached to a hollow cylindrical shaft table 29 through a bearing. The lower surface of this shaft table 29 is affixed to a support plate 32 below the partition plate 14 of the housing 11, and the upper surface of the shaft table 29 contacts the lower surface of the unit main body 21 to support it. The motor m2 is fastened to this support plate 32. As this motor m2 is activated, the wafer stage unit 20 undergoes a rotary reciprocating motion around a rotary shaft Ct within the same plane as the surface of the wafer stage 23 (in the direction shown by arrow R5 in
As shown in
As shown, the parallel motion mechanism is comprised of a mobile plate 33 which is positioned between the partition plate 14 of the housing 11 and the support plate 32 and is attached to the partition plate 14 through a linear guide 35 so as to be movable in a “first direction” (indicated by arrow X in
As shown in
The notch polishing part 40 may also include a mechanism for causing the notch polishing head 44 to undergo a reciprocating motion perpendicularly to the surface of the wafer W while the tape 43 is pressed against the notch. Although not shown, this mechanism may comprise a linear guide extending perpendicularly to the surface of the wafer stage 23 and a crank shaft mechanism for moving the notch polishing head 44 reciprocatingly by means of a motor.
The notch polishing part 40 may further include another mechanism for causing the notch polishing head 44 to undergo a rotary reciprocating motion around the notch (in the direction shown by arrow R3 in
The notch polishing part 40 may still further be provided with a nozzle 48 for supplying the notch with a polishing liquid of a slurry form having abrading particles dispersed in water or a water-based reactive liquid as well as cooling water.
The tape 43 may be of a woven or non-woven cloth or a foamed material. A base film in the form of a tape made of a plastic material or a tape having a polishing layer with abrading particles fastened by means of a resin binder may be used. Examples of abrading particles include diamond particles with average diameter in the range of 0.1 μm-5.0 μm and SiC particles with average diameter in the range of 0.1 μm-5.0 μm. Polyester and polyurethane type resin binders can be used. Examples of base film include films of a flexible material such as polyester, polyurethane and polyethylene terephthalate.
It is preferable to use a tape comprising a polishing layer having abrading particles affixed by a resin binder together with a polishing liquid having abrading particles dispersed in water and/or cooling water. This is because the polishing can be effected without using any water-based reactive liquid and hence the contamination of the water and the interior of the housing 11 (that is, the contamination of each constituent component set inside the housing 11) can be prevented more dependably.
According to practical examples, the width of the tape 43 is within the range of 1 mm-10 mm, the length of the tape 43 is several tens of meters and the tape 43 is wound around a cylindrical core material (shown at 46′ in
The polishing of the notch is carried out by moving the wafer held by the wafer stage 23 parallel to the surface of the wafer stage 23 by the stage moving part 30 so as to press the notch to the tape 43 of the notch polishing part 40 and causing the wafer stage 23 to undergo a rotary reciprocating motion around the notch (in the direction shown by arrow R5 in
Although an example was described above wherein the notch is polished by using a tape, this is not intended to limit the scope of the invention. The notch may be polished instead by using a disk-shaped pad of a known kind with the outer periphery not having the same shape as that of the notch.
As shown in
As shown in
The tape supplying part 55 comprises a supply roll 56, a take-up roller 57 for winding up the tape 53 from the supply roll 56 through the contact pad 51 and a driving part (not shown) for driving the take-up roller 57 for winding up the tape 53. The tape 53 passing over the contact pad 51 is pressed against the beveled part of the wafer W through the contact pad 51 and the beveled part is thereby polished.
The bevel polishing part 50 may also include a mechanism for causing the bevel polishing head 54 to undergo a rotary reciprocating motion around a beveled part perpendicularly to the surface of the wafer W (in the direction shown by arrow R4 in
The bevel polishing part 50 may further be provided with a nozzle 58 for supplying the beveled part with a polishing liquid of a slurry form having abrading particles dispersed in water or a water-based reactive liquid as well as cooling water.
The tape 53 may be a woven or non-woven cloth or a foamed material. A base film in the form of a tape made of a plastic material or a tape having a polishing layer with abrading particles fastened by means of a resin binder may be used. Examples of abrading particles include diamond particles with average diameter in the range of 0.1 μm-5.0 μm and SiC particles with average diameter in the range of 0.1 μm-5.0 μm. Polyester and polyurethane type resin binders can be used. Examples of base film include films of a flexible material such as polyester, polyurethane and polyethylene terephthalate.
It is preferable to use a tape comprising a polishing layer having abrading particles affixed by a resin binder together with a polishing liquid having abrading particles dispersed in water and/or cooling water. This is because the polishing can be effected without using any water-based reactive liquid and hence the contamination of the water and the interior of the housing 11 (that is, the contamination of each constituent component set inside the housing 11) can be prevented more dependably.
According to practical examples, the width of the tape 53 is within the range of 1 mm-10 mm, the length of the tape 43 is several tens of meters and the tape 53 is wound around a cylindrical core material.
If a tape with a polishing layer having abrading particles with average diameter less than 2.0 μm is used to polish the beveled part of a wafer W, it is possible to adjust the diameter of the wafer W to a specified length. If a tape with a polishing layer having abrading particles with average diameter 2.0 μm or less is used, a finishing work can be carried out on the beveled part of the wafer W.
If the average diameter of abrading particles affixed to the polishing layer is thus selected and the bevel polishing head 54 is caused to undergo a rotary reciprocating motion around the beveled part in the direction of arrow R4 during the polishing process, it is possible to form the upper and lower sloped surfaces of the wafer W (indicated by P and Q in
The beveled part of the wafer W is polished by moving the wafer W held by the wafer stage 23 parallel to the surface of the wafer stage 23 by using the stage moving part 30, pressing the beveled part of the wafer W against the tape and rotating the wafer stage 23 in the direction of arrow R1 shown in
The bevel polishing part 50, like the notch polishing part 40, may be provided with a diameter detecting part for detecting the outer diameter of the tape 54 wound around the supply roll 56. This detecting part is like that for the notch polishing part 40, comprising an optical sensor having a light emitter and a light receiver and having the supply roll disposed between the light emitter and the light receiver. The quantity of light received by the light receiver is measured and the outer diameter of the tape 53 remaining wound around the supply roll 56 is thereby determined. The outer diameter of the tape 53 thus detected is transmitted to a controller for a motor for supplying the tape 53 from the supply roll 56 such that the torque value of the motor will vary smoothly and the tension in the tape 53 will remain constant.
As shown in
The waterproof cover 36 may be a single structure as shown in
Flexible sheets not permeable to liquids made, for example, of a plastic material are used as the waterproof cover 36 (or outer and inner covers 37 and 38). Flexible sheets made of a foamed material may preferably be used.
As shown in
The notch position detecting part comprises at least one optical sensor (three sensors 91, 92 and 93 being shown). Each optical sensor may be structured with a light emitter and a light receiver arranged such that the notch N on the watch W being held by the wafer stage 23 passes between them. As the wafer W rotates (as shown by arrow R1), light from the light emitter is received by the light receiver only when the notch N is directly below the light emitter. This is how the position of the notch N is detected.
Alternatively, an optical sensor of the straight light regression type may be used. An optical sensor of this type is a laser sensor having a light emitter and a light receiver disposed on the same side and a reflector disposed opposite to them for reflecting the light from the light emitter. In this case, the laser light from the light emitter is reflected by the reflector and detected by the light receiver only when the notch N on the wafer W is passing directly below the light emitter and this is how the position of the notch N is detected.
According to this invention, the rotary motion of the wafer stage 23 is stopped when the position of the notch N is detected as explained above such that the notch N will face the tape of the notch polishing part.
According to the illustrated example, the notch detecting part is provided with three optical sensors 91, 92 and 93. When the wafer stage 23 holding the wafer W is rotating with a rotary speed within a first range (such as 12 rpm or slower and 4 rpm or faster), it is the first optical sensor 91 that detects the position of the notch N. If the wafer stage 23 is rotating at a lower rotary speed within a second range (such as less than 4 rpm and 1 rpm or faster), it is the second optical sensor 92 that detects the notch position. If the wafer stage 23 is rotating at a still lower rotary speed within a third range (such as less than 1 rpm), it is the third optical sensor 93 that detects the notch position.
Next,
In summary, as the wafer wage 23 decelerates until it stops, the position of the notch N is detected sequentially by the first, second and third optical sensors 91, 92 and 93 and in a stepwise manner. The third optical sensor 93 is adapted to detect the position of the deepest part of the notch N and hence to detect the position of the notch N most accurately within ±0.1°. Since the position of the notch N is detected merely while the wafer W is rotationally decelerating in the same direction, the detection can be made in a short measuring time.
The sensor assembly 90 is provided with a displacement detecting part for detecting the displacement of the wafer W in its radial direction as being held by the wafer stage 23. Such a displacement may be a result of the wears on the knobs 83 on the first and second chuck hands 81 and 82.
As shown in
The displacement may be expressed by using the center (Ch) of the wafer W as the origin, and defining a polar coordinate system by using an arbitrary line (r) radially extending therefrom as a reference direction, in terms of the angle θ from this reference line r and the distance between the defined origin Ch and the center Cs of the wafer stage 23.
As shown in
Explained more in detail with reference to
The sensor assembly 90 further comprises a waterproofing part for preventing damages to the optical sensors 91, 92 and 93 by the cooling liquid and the polishing liquid used for the tape-polishing of the wafer W. As shown in
The bevel polishing part 50 may further comprise a second displacement detecting part for detecting the displacement of the wafer W while the beveled part of the wafer W is being polished. As shown in
Although not shown, the device 10 according to this invention may further comprise a cleaning part for maintaining the interior of the housing 11 clean. Such a cleaning part may comprise an air inlet provided to the ceiling of the upper chamber 15 of the housing 11, an air discharge outlet provided to a lower portion on a side surface of the upper chamber 15 of the housing 11 and an external pump connected to this outlet such that the air that flows in through the air inlet will flow inside the housing 11 along its side surfaces. With an air flow thus formed inside the housing 11, particles can be discharged outward without becoming attached to the surface of the wafer W held by the wafer stage 23.
The device 10 according to this invention may further comprise a dryness preventing part for supplying pure water to the wafer W held by the wafer stage 23 such that the wafer W is prevented from becoming dry after each time it is polished by the notch polishing part 40 and the bevel polishing part 50 to be transported to the place of the next processing. As shown in
Although two nozzles n1 and n2 are used according to the illustrated example, only one nozzle may be provided or more than two of them may be used. The nozzles are positioned such that the wafer W will not collide with them as the wafer stage 23 is caused to undergo the rotary reciprocating motion within the same plane as the surface of the wafer stage 23.
A method for polishing the peripheral edge part (both the notch and the beveled part) of a wafer W is explained next.
After the shutter 13 is driven by an air cylinder to open the opening 12 on the side surface of the housing 11 and the wafer W is transported into the upper chamber 15 of the housing 11 by using the robot hand 13′, the wafer W is brought directly above the wafer stage 23 and the first and second chuck hands 81 and 82 at the wafer delivery position L2 are used to grasp the wafer W. At this moment, the center of the wafer W comes to a position directly above the center of the wafer stage 23 which is directly below. Thereafter, the robot hard 13′ is retracted from the housing 11 and the shutter 13 is driven by the air cylinder to close the opening 12 of the housing 11.
While the wafer W remains thus grasped, the first and second chuck hands 81 and 82 are lowered to the wafer-setting position L3 and then are opened such that the wafer W is set on the pad 24. The first and second chuck hands 81 and 82 are raised to the retracted position L1. The vacuum pump is activated to hold the wafer W, adsorbed onto the wafer stage 23.
The sensor assembly 90 is rotated to position the optical sensors 91, 92 and 93 on the periphery of the wafer W held by the wafer stage 23, and the wafer stage 23 is rotated in the direction of arrow R1 to detect the position of the notch N. While the wafer stage 23 is still rotating, the positional displacement of the wafer W is also detected.
After the positional displacement of the wafer W is detected, the first and second chuck hands 81 and 82 are lowered to the wafer setting position L3 to grasp and lift up the wafer W. The wafer W is released from the suction force towards the wafer stage 23 by stopping the operation of the vacuum pump when the wafer W has been lifted up just a little. The wafer stage 23 is moved by the amount of the detected displacement, and the first and second chuck hands 81 and 82 are lowered to the wafer setting position L3 while grasping the wafer W as described above. These chuck hands 81 and 82 are then opened so as to set the wafer W on the wafer stage 23 and the vacuum pump is operated to hold the wafer W on the wafer stage 23 by suction. Thereafter, the wafer stage 23 is rotated as shown by arrow R1 as described above to detect the position of the notch by means of the optical sensors 91, 92 and 93 of the sensor assembly 90 as well as the positional displacement of the wafer W. This process may be repeated until the positional displacement ceases to be detected.
Next, the wafer stage 23 is moved towards the notch polishing part 40 such that the notch on the wafer W is pressed against the tape 43 of the notch polishing head 44. While a polishing liquid is supplied to the notch on the wafer W through the nozzle 48, the tape 43 is caused to run with the tape 43 remaining pressed against the notch and the wafer stage 23 is caused to undergo a rotary reciprocating motion in the direction of arrow R5 around the position of the notch in the same plane as the surface of the wafer W so as to polish the notch on the wafer W.
The notch is cooled during the polishing process by means of the polishing liquid supplied to the wafer W and the coefficient of friction at the notch is reduced. Debris produced by the polishing is prevented from scattering around. Although some debris may scatter around, scattered debris is washed off by the polishing liquid and does not become attached to the wafer W.
The notch polishing head 44 may be caused to undergo a vertical reciprocating motion or a rotary reciprocating motion (in the direction of arrow R3) to polish the edge E (shown in
Next, the wafer stage 23 is moved towards the bevel polishing part 50 and the beveled part of the wafer W is pressed against the tape 53 through the contact pad 51. While the wafer stage 23 is thus moved, pure water is supplied to the wafer W through the nozzles n1 and n2 in order to prevent it from becoming dry.
The beveled part of the wafer W is polished by causing the tape 53 to run and the wafer stage 23 to rotate while the beveled part of the wafer W is pressed against the tape 53 and the polishing liquid is supplied to the beveled part of the wafer W through the nozzle 58.
The beveled part is cooled during the polishing process by means of the polishing liquid supplied to the wafer W and the coefficient of friction at the beveled part is reduced. Debris produced by the polishing is prevented from scattering around. Although some debris may scatter around, scattered debris is washed off by the polishing liquid and does not become attached to the wafer W.
The bevel polishing head 54 may be caused to undergo a vertical reciprocating motion or a rotary reciprocating motion (in the direction of arrow R4) to polish the edge E of the beveled part.
Although an example was shown wherein the polishing of the beveled part is done after the notch is polished, it goes without saying that the notch may be polished after the beveled part is polished.
The positional displacement of the wafer W may be detected while the beveled part is being polished. If a displacement is detected, this is fed back to the stage moving part 30 for correcting the positional displacement of the wafer W in its radial direction.
After both the beveled part and the notch are polished, the wafer stage 23 is returned to its original position. The first and second chuck hands 81 and 82 are lowered from the retracted position L1 to the wafer setting position L3 to grasp and lift up the wafer W. When the wafer W has been lifted a little, the vacuum pump is stopped and releases the wafer W from the suctioned condition and the first and second chuck hands 81 and 82 reach the wafer delivery position L2. The air cylinder drives the shutter 13 to open the opening 12 of the housing 11 and the robot hand 13′ enters the housing 11 and comes to a position below the wafer W. The first and second chuck hands 81 and 82 open such that the wafer W is placed on the robot hand 13′ and is transported out of the housing 11.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2005-121464 | Apr 2005 | JP | national |
This application is a continuation of International Application No. PCT/JP2006/308492 filed Apr. 18, 2006, that was amended on Sep. 14, 2006 and claims priority on Japanese Patent Application 2005-121464 filed Apr. 19, 2005.
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| Number | Date | Country | |
|---|---|---|---|
| 20090093192 A1 | Apr 2009 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2006/308492 | Apr 2006 | US |
| Child | 11911808 | US |
