Integrated circuits are typically formed on substrates, particularly silicon wafers, by the sequential deposition of conductive, semiconductive or insulative layers. After each layer is deposited, the deposited layer is often etched to create circuitry features. As a series of layers are sequentially deposited and etched, the outer or uppermost surface of the substrate, i.e., the exposed surface of the substrate, can become increasingly non-planar. This non-planar surface may present problems in the photolithographic steps of the integrated circuit fabrication process. Therefore, there is often a need to periodically planarize the substrate surface.
Chemical mechanical polishing (CMP) is one accepted method of planarization. This planarization method typically includes mounting a substrate on a carrier or polishing head using a load cup assembly. The exposed surface of the substrate is placed against a rotating polishing pad. The polishing pad may be either a “standard” or a fixed-abrasive pad. A standard polishing pad has a durable roughened surface, whereas a fixed-abrasive pad typically has abrasive particles held in a containment media. The polishing head provides a controllable load, i.e., pressure, on the substrate to push it against the polishing pad. A polishing slurry, including at least one chemically-reactive agent, and abrasive particles, if a standard pad is used, is supplied to the surface of the polishing pad.
The polishing head can undergo periodic maintenance in which the head is disassembled, worn parts replaced and then reassembled. Prior to returning the head to polishing additional wafers, the refurbished head can be tested at a test station to determine whether the head operates properly before using it on expensive wafers or other semiconductor substrates.
In accordance with one aspect of the description provided herein, a polishing head is tested in a test station having a pedestal for supporting a test wafer and a controllable pedestal actuator to move a pedestal central wafer support surface and a test wafer toward the polishing head. The pedestal may be moved between a first vertical position vertically displaced from the polishing head, and a second vertical position vertically closer to the polishing head to facilitate polishing head testing.
In one embodiment, the testing includes testing a wafer loss sensor of the head. A wafer loss sensor test or other polishing head tests may include applying vacuum pressure to a membrane chamber of the head to pick up a first test wafer disposed on the pedestal central wafer support surface. The testing may also include applying pressure to an inner tube chamber of the head prior to applying the vacuum pressure to the membrane chamber and monitoring the pressure in the inner tube chamber while applying the vacuum pressure to the membrane chamber.
In another aspect of the present description, the test wafer may be positioned using a positioner having a first plurality of test wafer engagement members positioned around the pedestal central wafer support surface. The test wafer engagement members engage the test wafer to position the test wafer with respect to the pedestal central wafer support surface. In one embodiment, the wafer positioner comprises a ring member adapted to carry the first plurality of test wafer engagement members distributed about a first circumference of the ring member.
In yet another aspect, polishing head testing may include positioning a test wafer having a second diameter wider than the first diameter using a positioner having a second plurality of test wafer engagement members positioned around an outer wafer support surface disposed around the pedestal central wafer support surface and adapted to support a test wafer. The second plurality of test wafer engagement members may be distributed about a second circumference of the ring member, the second circumference having a wider diameter than the first circumference.
In still another aspect, the test station may have a removable cover plate having its own wafer support surface. The cover plate may be removed to expose the pedestal and test wafer positioner.
There are additional aspects to the present inventions. It should therefore be understood that the preceding is merely a brief summary of some embodiments and aspects of the present inventions. Additional embodiments and aspects are described and claimed. The preceding summary therefore is not meant to limit the scope of this description.
a is a schematic partial side cross-sectional view of the test wafer hold and transfer system shown with a cover plate.
b is an exploded schematic partial side cross-sectional view of the test wafer hold and transfer system shown without a cover plate.
a-6g illustrate one example of operations of the test wafer hold and transfer system to test a polishing head.
a and 7b are schematic diagrams illustrating operation of a wafer loss sensor of the polishing head of
A test station in accordance with one embodiment of the present invention is indicated generally at 10 in
In accordance with one aspect of the present description, the test station 10 further includes a test wafer hold and transfer system 17 which includes a movable pedestal 19. As described in greater detail below, the test wafer hold and transfer system 17 positions a test wafer relative to the polishing head 16 to facilitate testing of the polishing head 16. For example, the test wafer hold and transfer system 17 can provide for simulation of the loading of a wafer by the load cup assembly of a CMP tool.
As described in greater detail in U.S. Pat. No. 7,089,782, a polishing head such as the head 16 of
The polishing head 16 also has three pressure sealed chambers, that is, a retaining ring chamber 20, an inner tube chamber 22 and a membrane chamber 24. The test station 10 can apply various tests to the chambers to ensure proper sealing and operation. It is appreciated that the number and types of chambers may vary from head type to head type. For example, the head may have from three to eight chambers.
In the head 16 of the illustrated embodiment, the retaining ring chamber 20 is located between a housing 26 and a base 28 of the head 16. The retaining ring chamber 20 is pressurized to apply a load, i.e., a downward pressure, to the base 28 during a wafer polishing operation. A rolling diaphragm 29 flexibly couples the housing to the base 28 and permits the expansion and contraction of the retaining ring chamber 20. In this manner, the vertical position of the base 28 relative to a polishing pad is controlled by the pressure in the retaining ring chamber 20.
A flexible membrane 30 extends below a support structure 32 to provide a mounting surface 34 for the wafer or other semiconductor substrate 36 to be polished. Pressurization of the membrane chamber 24 positioned between the base 28 and support structure 32 forces flexible membrane 30 downwardly to press the substrate against the polishing pad. A flexure 38 flexibly couples the support structure 32 to the base 28 and permits the expansion and contraction of the membrane chamber 24.
Another elastic and flexible membrane 40 may be attached to a lower surface of base 28 by a clamp ring or other suitable fastener to define the inner tube chamber 22. Pressurized fluid such as air may be directed into or out of the inner tube chamber 22 and thereby control a downward pressure on support structure 32 and flexible membrane 30.
The housing 26 is connected to a spindle 44 of the polishing system used to rotate the head 16 therewith during polishing about an axis of rotation 46 which is substantially perpendicular to the surface of the polishing pad during polishing. Three pressure lines 50, 52 and 54 direct fluid such as air or nitrogen to each of the chambers 20,22 and 24 either at a pressure above ambient (pressurized) or below ambient (vacuum pressure).
As shown in
The head mount actuator 60 includes a servo motor assembly 70 which is controlled by the controller 62 through suitable driver circuits. It is appreciated that other types of motors may be used to actuate the polishing head to various vertical positions, depending upon the particular application.
The output of the servo motor assembly 70 is coupled to a vertical carriage assembly 78 which guides the mount arm 66 and restricts the movement of the mount arm and hence the head 16 to linear, nonrotational movements along the Z-axis. The carriage assembly 78 includes a carriage 80 to which the mount arm 66 is mounted by a pair of braces 81. The carriage 80 has a pair of guide bars 82 which are adapted to slide along guide rails 86 mounted on a vertical support plate 90 to guide the carriage 80 and hence the head 16 in a vertical, non-pivoting, linear movement up and down along the Z-axis. The support plate 90 is mounted by braces 92 to a horizontal support plate 94 of the platform 12. It is appreciated that other mechanical arrangements may be selected to guide the polishing head along one or more selected axes of movement.
In accordance with another aspect of the present description, the cavity 102 of the support plate 94 of the frame 12, is sized and shaped so as to permit the top surface 110 of the support plate 100 to be flush with or recessed with respect to the top surface 112 of the support plate 94. Such an arrangement can facilitate placement of an optional cover plate 120 on the support plate 94 to cover the test wafer hold and transfer system 17. In some prior systems, a cover plate similar to the plate 120 is often used to provide a test wafer support surface similar to the surface 122 for polishing head testing purposes.
Accordingly, in the illustrated embodiment of
The test wafer hold and transfer system 17 further includes a test wafer positioner 140 which has a plurality of test wafer engagement members 142 carried by a ring member 143 (
As previously mentioned, the test station 10 may be used to test a variety of sensors, chambers and other structures of a polishing head.
However, should the wafer drop from the head 16, ambient pressure acting on the membrane 30 drives the membrane 30 and the support structure upwardly into the membrane chamber as shown in
The valves 234, 244 and 254 are controlled by the controller 62. To conserve pressure in a particular chamber, the vent valve 254, pressure valve 234 and vacuum valve 254 are closed. By closing these valves, the chamber is isolated from being further pressurized, vacuumed or vented. The pressure within the chamber may be monitored by the controller 62 through a pressure sensor 260 such as a transducer fluidically coupled to the associated chamber. If the chamber pressure drops after closing the control valves 234, 244 and 254, the presence of a leak is indicated. As previously mentioned, if the pressure in the inner tube chamber 22 follows a curve such as that shown in
The test station 10 can test the chambers of the polishing head for pressure and vacuum leaks including leaks across the various chambers (cross talk) Testing includes height and time of rise as well as valve and sensor tests.
In a first operation, the test wafer is placed (block 266) on a wafer positioner such as the wafer positioner 140. In the illustrated embodiment, the test wafer engagement members 142 of the wafer positioner 140 are generally finger-shaped and each includes an angled ramp surface 270 (
In the illustrated embodiment, the pedestal 19 and the test wafer positioner 140 are supported by a pedestal housing 280 affixed to the support plate 100 of the test wafer hold and transfer system 17. The pedestal 19 and test wafer positioner 140 are supported in the test station 10 such that the centers of the pedestal 19 and test wafer positioner 140 are coaxially aligned with the center axis 46 (
Once the test wafer has been positioned by the wafer positioner 140, the pedestal may be raised (block 290) causing the pedestal support surface 144 of the pedestal 19 to engage the underside of the test wafer. Continued upward motion of the pedestal 19 lifts the test wafer off the wafer positioner 140 and moves the test wafer vertically upward toward the polishing head 16 as shown in
In the illustrated embodiment, the pedestal 19 has a central connecting rod 292 which is journaled for a sliding, vertical motion within the pedestal housing 280. A pedestal actuator 294 coupled to the pedestal connecting rod 292 vertically actuates the pedestal 19 between a first, lowered position depicted in
In the illustrated embodiment, the pedestal actuator 294 includes a pneumatic cylinder 300 which is driven by pneumatic circuits 302 controlled by the test station controller 62. The pneumatic cylinder 300 is connected by a drive member 304 to the connecting rod of the pedestal 19. Upon application of suitable pneumatic pressures to the pneumatic cylinder 300, the drive member 304 and hence the pedestal 19 are selectively driven in upward or downward movements. The range of the vertical motion may be limited by suitable stops or by the controller 62, depending upon the particular application. It is appreciated that other types of actuators may be used to elevate the pedestal 19. Such other actuators includes electric motors and servos.
Prior to initiating a test of the polishing head 16, the controller 62 can control the linear actuator 60 (
For example, in a wafer loss sensor test, the polishing head may be displaced above the top surface of the test wafer prior to loading the test wafer by a distance such as 1.5 mm, for example. At this height, the controller 62 can cause the head 16 to begin the process of loading the test wafer onto the polishing head. The membrane chamber 24 (
To load the test wafer, the inner tube chamber 24 is also pressurized to apply pressure to push the perimeter of the membrane 30 against the perimeter of the test wafer. The pressure in the inner tube chamber is then conserved at that pressure to test for leaks in the inner tube chamber as set forth above. If the pressure in the inner tube chamber remains steady at the preset pressurized level, a proper sealing of the inner tube chamber is indicated. In the illustrated embodiment, it is preferred that the inner tube chamber be pressurized to a level of 1 psi above ambient for the wafer loss sensor test. Other pressures in a range of 0-3 psi may also be used. The particular values will vary, depending upon the particular application.
Once maintenance of the pressure in the inner tube chamber 22 has been confirmed at the preset value, and air pockets between the membrane 30 and the wafer top surface expressed away, a vacuum pressure is applied to the membrane chamber 24 to finish loading the test wafer. The polishing head with the loaded test 15 wafer may then be withdrawn from the pedestal 19 to another height above the pedestal 19 as shown in
If the wafer is properly loaded in a manner similar to that shown in
In the illustrated embodiment, it is preferred for the head test station 10 to be able to precisely position the polishing head at a precise, electronically controlled position to facilitate testing of the polishing head as described in U.S. Pat. No. 7,089,782. For example, in the wafer loss sensor test with a test wafer as described above, if the polishing head is positioned too close to the test wafer prior to loading the wafer, it is believed that the membrane 30 and support structure 32 can be driven up into the membrane chamber 24, causing the wafer loss sensor 18 to be improperly actuated. Conversely, if the polishing head is positioned too far from the test wafer prior to loading the wafer, the test wafer may not be properly picked up. Hence, vacuum pressure applied to the membrane chamber 24 to pick up the wafer can instead cause the membrane 30 and support structure 32 to be withdrawn into the membrane chamber 24, again resulting in improper actuation of the wafer loss sensor 18. A vertical position of the polishing head spaced within a range of 1-2 mm above the test surface is believed appropriate for many such applications. Other distances may also be used. The particular values will vary, depending upon the particular application.
Because of the many positions to which the head may be programmed to move, the head test station in effect provides continuous control over the movement of the head relative to the raised pedestal 19. The test position and load position of the head may be defined relative to the raised pedestal 19 for many different types of heads. Any differences in the size of the heads including differences in thickness may be readily accommodated by programming the actuator control to move the head to the optimum positions for that particular head type.
Upon conclusion of testing of the polishing head 16 using a test wafer, or as part of testing, the polishing head 16 can return the test wafer to the pedestal 19. Accordingly, the controller 62 controls the linear actuator 60 to position the polishing head 16 to a vertical position adjacent the pedestal 19 as shown in
Once the test wafer has been returned to the pedestal 19 by the polishing head 60, the pedestal 19 may be lowered (block 314) to the wafer positioner 140. Continued downward motion of the pedestal 19 deposits the test wafer on the wafer positioner 140 and realigns the center of test wafer with respect to the center of the polishing head 16 as appropriate. Testing may then be concluded or additional testing of the polishing head may then be performed as appropriate. Such additional testing may include or exclude use of a test wafer 36 or movement of the pedestal 19, depending upon the particular application.
In the illustrated embodiment, downward vertical motion of the pedestal 19 terminates at the lower position below the wafer positioner 140 as depicted in
An example of polishing head testing has been provided in which a test wafer is aligned by the wafer positioner 140 and lifted to the polishing head 16 in preparation for the polishing head 16 to load the test wafer. It is appreciated that some polishing head tests utilizing a test station in accordance with the present description may omit a test wafer loading operation, or a test wafer alignment operation, or a test wafer lifting operation, depending upon the particular application.
As best seen in
In the illustrated embodiment, the test wafer engagement members 442a, like the members 142, are generally finger-shaped and each includes an angled ramp surface 270a (
The test wafer engagement members 442b of the wafer positioner 440 are similarly positioned around the central wafer support surface 444 of the pedestal 450, but at a wider circumference than the wafer engagement members 442a. The test wafer engagement members 442b are adapted to engage and position a test wafer 460 with respect to the pedestal central wafer support surface 444 prior to the pedestal 450 receiving the test wafer 460 and transporting the test wafer 460 up to a polishing head. As in apparent in
The test wafer engagement members 442b, like the members 442a, are generally finger-shaped and each includes an angled ramp surface 270b (
In the illustrated embodiment, the pedestal 450 includes a plurality of flanges 470 (
In one embodiment, a pedestal such as the pedestal 450 may be dedicated to test wafers of a particular size such as the test wafers 36 or the test wafers 460. Alternatively, the pedestal 450 may be able to accommodate test wafers of different sizes. For example, an upper surface 484 of the pedestal flanges 470 may be adapted to provide a pedestal outer wafer support surface to engage and support a larger test wafer such as a test wafer 460. In another example, the test wafer hold and transfer system 400 may include a pedestal adapter plate 490 (
As shown in
Referring again to
As described in greater detail in U.S. Pat. No. 7,089,782, the test station 10 may include a lateral carriage assembly to facilitate loading and mounting a polishing head 16 into the test station for testing. It is appreciated that the details and 30 particulars of such a lateral carriage assembly may vary, depending upon the particular application. Still further, the test station 10 may include a wafer chuck to chuck a test wafer in place for testing the polishing head. Again, the details of such a wafer chuck will depend upon the particular application.
It will, of course, be understood that modifications of the illustrated embodiments, in their various aspects, will be apparent to those skilled in the art, some being apparent only after study, others being matters of routine mechanical and electronic design. Other embodiments are also possible, their specific designs depending upon the particular application. As such, the scope of this description should not be limited by the particular embodiments described herein but should be defined by the appended claims and equivalents thereof.
This application claims priority to and is a continuation of U.S. patent application Ser. No. 11/686,868, filed Mar. 15, 2007, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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Parent | 11686868 | Mar 2007 | US |
Child | 12829971 | US |