Patent Application
20230142778
The present disclosure relates generally to processing workpieces and more particularly to automated replacement of replaceable parts in a system for processing workpieces, such as semiconductor workpieces, under vacuum.
Processing systems which expose workpieces such as, semiconductor wafers or other suitable substrates, to an overall treatment regimen for forming semiconductor devices or other devices can perform a plurality of treatment steps, such as plasma processing (e.g., strip etch, etc.), thermal treatment (e.g. annealing), deposition (e.g., chemical vapor deposition), etc. To carry out these treatment steps, a system can include one or robots to move workpieces a number of different times, for example, into the system, between various processing chambers, and out of the system. In semiconductor workpiece processing, it can be necessary from time to time to perform routine maintenance and/or preventative maintenance on processing systems. This can require, in certain instances, physical replacement of certain parts in the processing systems.
Aspects and advantages of embodiments of the present disclosure will be set forth in prat in the following description, or can be learned from the description, or can be learned through practice of the invention.
An example embodiment of the present disclosure is directed to a portable device (e.g., a storage cassette) for use in an automated replaceable part (e.g., focus ring) replacement system for use with a workpiece processing system (e.g., for processing semiconductor wafers). The cassette is configured to hold one or more replaceable parts, one or more workpieces and one or more pedestal protectors. The cassette also includes a divider configured to separate the one or more replacement parts from the one or more workpieces and/or one or more pedestal protectors. The cassette is configured to be disposed in a storage chamber of a workpiece processing apparatus to facilitate automated replacement of replacement parts in one or more processing chambers.
Other example aspects are directed to systems and methods for processing a workpiece. Variations and modifications can be made to example aspects of the present disclosure.
These and other features, aspects and advantages of various embodiments will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the present disclosure and, together with the description, serve to explain the related principles.
Detailed discussion of embodiments directed to one of ordinary skill in the art are set forth in the specification, which makes reference to the appended figures, in which:
Reference now will be made in detail to embodiments, one or more examples of which are illustrated in the drawings. Each example is provided by way of explanation of the embodiments, not limitation of the present disclosure. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made to the embodiments without departing from the scope or spirit of the present disclosure. For instance, features illustrated or described as part of one embodiment can be used with another embodiment to yield a still further embodiment. Thus, it is intended that aspects of the present disclosure cover such modifications and variations.
Example aspects of the present disclosure are directed to systems and methods for automated replacement of replaceable parts in semiconductor workpiece processing equipment. The systems and methods can provide for manipulating the replaceable parts through a vacuum apparatus. Example replaceable parts can include focus rings used in plasma processing chambers (e.g., plasma dry etch chambers) for semiconductor workpieces.
In workpiece processing systems, preventative maintenance can be performed by trained technicians that perform physical acts of labor to replace replaceable parts, such as focus rings in plasma dry etch chambers. In vacuum processing systems, this can require venting of the processing chambers to atmosphere and opening of the processing chambers for access. This can lead to expensive downtime in semiconductor device manufacturing processes. In addition, when a processing chamber is open to the environment, the potential contamination of other processing parts has increased risk and other chamber parts can need to be removed and/or replaced.
For instance, a process for performing maintenance on semiconductor processing equipment has included monitoring for a trigger condition, such as workpiece count, plasma exposure time (e.g., for a plasma processing tool), etc. Upon occurrence of a trigger condition, a vacuum processing chamber can be taken offline, reducing workpiece throughput. A service technician can implement processing chamber conditioning (e.g., plasma cleaning) to put the vacuum processing chamber in a safe opening state. After conditioning, the technician can vent the vacuum processing chamber. The technician can open the vacuum processing chamber to access the interior and start removal of certain chamber parts (e.g., focus rings). After cleaning of any unremoved parts, replacement parts can be added to the processing chamber and the vacuum processing chamber can be closed and evacuated. Once back online, some qualification workpieces can be run through the vacuum processing chamber. Once the vacuum processing chamber is producing a successful result, the processing chamber can be put back into semiconductor device production.
According to example aspects of the present disclosure, workpiece processing equipment can be configured to automatically replace certain process chamber parts through robotics that are typically found in workpiece processing equipment. More particularly, unused replaceable parts can be loaded into a storage area and made accessible to the vacuum transport robotics. The robotics can interface with a workpiece processing module to remove a consumed (used) chamber part and then replace it with a new (non-consumed) chamber part. The used part can then be returned to the storage area where it can be removed without the need to disrupt the workpiece processing chamber.
In some embodiments, the systems and methods according to example aspects of the present disclosure can be used to replace focus rings used in plasma processing chambers. A focus ring can be positioned around a periphery of a workpiece supported on a workpiece support (e.g., having cathode or bias electrode) in a plasma processing apparatus. The focus ring can be used, for instance, to shape the plasma in the vicinity of the workpiece. During plasma processing in a plasma processing chamber, the focus ring can be exposed to plasma and as such is exposed to deposition and erosion. As a result, focus rings may need to be periodically replaced in plasma processing chambers as part of preventative maintenance for a workpiece processing system.
Aspects of the present disclosure are discussed with reference to a focus ring as a replaceable part. Those of ordinary skill in the art, using the disclosures provided herein, will understand that aspects of the present disclosure are applicable for replacing other replaceable parts in a vacuum processing chamber without deviating from the scope of the present disclosure.
In some embodiments, the systems can monitor for a trigger condition, such as a workpiece count, plasma exposure time, etc. Upon occurrence of the trigger condition, an in-situ plasma dry clean process can be implemented to prepare the vacuum processing chamber. Once the in-situ plasma dry clean process is complete, a lift mechanism outside of the vacuum processing chamber but coupled inside the chamber can use a set of pins to lift a focus ring that sits around a workpiece support in the vacuum processing chamber. After lifting the focus ring, a workpiece handling robot can enter the chamber and lift the ring off the pins in a vertical motion. The robot can retract and rotate to place the used focus ring on a shelf in a storage location. In some embodiments, the workpiece handling robot can hand off the focus ring to a second robot for placement into a storage location.
The robot can then move to a different shelf of the storage location and retrieve a new focus ring. After rotation to the vacuum processing module, the robot can extend to the needed position and the drop down to place the focus ring on the lift pins. After the robot retracts from the vacuum processing module, the system can lower the lifting pins and drop the ring into final position around the workpiece support (e.g., including cathode). A conditioning plasma can be used to stabilize process performance in the workpiece processing chamber and the vacuum processing chamber can be brought back online for normal operation. A test workpiece (e.g., obtained from the storage location) can be used to test the processing module with a test process prior to bringing the process module back online for normal operation.
Example aspects of the present disclosure are directed to a portable device (e.g., a storage cassette) for storing replaceable parts, such as focus rings, in an automated system for replacement of parts in a plasma processing system. In some embodiments, a storage cassette can hold a plurality of replacement parts (e.g., about 10 focus rings), a silicon wafer, and a pedestal cover (e.g., electrostatic chuck cover). The silicon wafer can be used as the test workpiece to provide verification of focus ring placement after replacement of the focus ring according to example embodiments of the present disclosure. The pedestal cover can allow for protection of the pedestal (e.g., electrostatic chuck) during focus ring replacement according to example embodiments of the present disclosure. The storage cassette can include a divider that separates the focus rings from the pedestal cover and/or the semiconductor wafer. The divider can assist with maintaining the cleanliness of the semiconductor wafer and the cover.
In some embodiments, the portable device (e.g., storage cassette) can be used to store multiple pieces of process kit to enable automated process kit replacement. The cassette can be installed in a storage chamber which can be attached to the integrated wafer processing system. The workpiece processing system can include a transfer module (with a workpiece handling robot) with one or more process modules attached to it.
In some embodiments, the storage cassette can include a base plate, and two vertical datum plates opposing each other that are mounted on the base plate. Multiple shelves can be mounted on the datum plates. Each shelf can include a pair of fins, one mounted on each datum plate. One example of process kit is a focus ring.
In some embodiments, there can be a plurality of shelves for holding a plurality of focus rings, such as six focus rings, seven focus rings, eight focus rings, nine focus rings, ten focus rings, eleven focus rings, twelve focus rings, or any other number of focus rings. There can be additional shelves acting as a temporary buffer, such as two additional shelves acting as a temporary buffer. Below the bottom focus ring shelf can be a divider plate that spans from one datum plate to another. Below the divider plate can be a shelf for holding a silicon wafer and a shelf for holding a pedestal cover. These two shelves can include fins with different geometries (e.g., different shapes and/or configurations) than the focus ring shelves.
In some embodiments, there can be a brace mounted across the top of the two datum plates to provide enhanced structural support. A cassette cover can be installed on the cassette to protect the contents of the cassette, as well as provide a grip location for moving the cassette. The cover can have two alignment pins that engage into the top of the cassette. Two rods are used to lock the cover to the cassette at the bottom.
In some embodiments, the cassette does not include any power assisted actuator or pneumatic actuator.
In some embodiments, a lift mechanism in the storage chamber can be used to move the portable device (e.g., storage cassette) up and down in a vertical direction to align one of the plurality of shelves with a slit. A workpiece handling robot can insert an endeffector through the slit in the storage chamber to grab one of the replaceable parts (e.g., focus ring, semiconductor wafer, pedestal cover, etc.).
in some embodiments, the portable device (e.g., storage cassette) can be configured for use in pressure ranges between vacuum and atmospheric pressure. In some embodiments, the portable device (e.g., storage cassette) can be configured for use in environments having temperature of about 50° C. or less. The portable device (e.g., storage cassette) can be configured for use in an inert environment.
In some embodiments, a method can include receiving a storage cassette into a storage chamber of a workpiece processing platform. The method can include vertically actuating the storage cassette to a first vertical position. The method can include grabbing with an endeffector a pedestal cover from the storage cassette. The pedestal cover can be placed on a pedestal of a processing station in the workpiece processing system.
The method can include obtaining a used replaceable part (e.g., focus ring) from a processing station. The method can include vertically actuating the storage cassette to a second vertical position and placing the used replaceable part (e.g., focus ring) on a shelf in the storage cassette. The method can include vertically actuating the storage cassette to a third vertical position and grabbing with an endeffector a clean replaceable part (e.g. focus ring). The clean replaceable part can be placed on the processing station in the workpiece processing system.
The method can include removing the pedestal cover from the processing station. The method can include vertically actuating the storage cassette to the first vertical position to place the pedestal cover back into the storage cassette. The method can include vertically actuating the storage cassette to a fourth vertical position and grabbing with the endeffector the semiconductor wafer from the storage cassette. The semiconductor wafer can be placed on the processing station to perform test processes with the clean replaceable part (e.g., focus ring). The method can include grabbing the semiconductor wafer with the endeffector. The method can include placing with the endeffector the semiconductor wafer back into the storage cassette.
Aspects of the present disclosure can provide a number of technical effects and benefits. For instance, the robotic arm motion pattern provided herein can facilitate access to replaceable parts in process chambers having multiple processing stations, such as two processing stations. Furthermore, the storage chamber provided herein allows for storage of used replaceable parts and retrieval of new replaceable parts for the process chambers without having to break the overall vacuum of the system. In sonic embodiments, test workpieces can be included in the storage chamber to be used in testing of replaceable parts after placement. The contact between the pins and the focus ring can prevent lateral movement of the focus ring as the focus ring is raised and lowered to ensure the focus ring is precisely concentric to the electrostatic chuck or other workpiece support. The end effector support elements provided herein can reduce total number of parts, which reduces costs, and simplifies control patterns for moving the end effector. Further, the spatial configuration of the support pads on the end effector can utilize existing openings of process chambers for moving replaceable parts into and out of process chambers. Locating the lift pin outside of the RF zone and having the lift pin penetrate the ground plane can reduce arcing risks associated with applying RF power (e.g. bias power) from a RF source to the bias electrode during a plasma process. Furthermore, there can be reduced interference (e.g., electrical and mechanical) between the lift pin and the focus ring. The portable device (e.g., storage cassette) can provide for a hardware mechanism for automated replacement of replaceable parts (e.g., focus rings) as well as verification. The portable device (e.g., storage cassette) can fit within tight clearances in a storage chamber attached to a workpiece processing system. The portable device (e.g., storage cassette) can include a divider to keep a test semiconductor water and/or pedestal cover clean during automated replacement of replaceable parts.
Referring now to the FIGS., example embodiments of the present disclosure will now be described.
The front end portion 112 can be configured to be maintained at atmospheric pressure and can be configured to engage workpiece input devices 118. The workpiece input devices 118 can include, for instance, cassettes, front opening unified pods, or other devices for supporting a plurality of workpieces. Workpiece input devices 118 can be used to provide preprocess workpieces to the processing system 100 or to receive post-process workpieces from the processing system 100.
The front end portion 112 can include one or more robots (not illustrated) for transferring workpieces from workpiece input devices 118 to, for instance, the loadlock chamber 114, such as to and from a workpiece column 110 located in the loadlock chamber 114. In one example, the robot in the front end portion 112 can transfer preprocess workpieces to the loadlock chamber 114 and can transfer post-process workpieces from the loadlock chamber 114 to one or more of the workpiece input devices 118. Any suitable robot for transferring workpieces can be used in the front end portion 112 without deviating from the scope of the present disclosure. Workpieces can be transferred to and or from the loadlock chamber 114 through a suitable slit, opening, or aperture.
The loadlock chamber 114 can include a workpiece column 110 configured to support a plurality of workpieces in a stacked arrangement. The workpiece column 110 can include, for instance, a plurality of shelves. Each shelf can be configured to support one or more workpieces. In one example implementation, the workpiece column 110 can include one or more shelves for supporting preprocess workpieces and one or more shelves for supporting post-process workpieces.
In some embodiments, appropriate valves can be provided in conjunction with the loadlock chamber 114 and other chambers to appropriately adjust the process pressure for processing the workpieces. In some embodiments, the loadlock chamber 114 and the transfer chamber 115 can be maintained at the same pressure. In this embodiment, there is no need to seal the loadlock chamber 114 from the transfer chamber 115. Indeed, in some embodiments, the loadlock chamber 114 and the transfer chamber 115 can be a part of the same chamber.
A single loadlock chamber 114 is illustrated in
The first process chamber 120 and the second process chamber 130 can be used to perform any of a variety of workpiece processing on the workpieces, such as vacuum anneal processes, surface treatment processes, dry strip processes, dry etch processes, deposition processes, and other processes. In some embodiments, one or more of the first process chamber 120 and the second process chamber 130 can include plasma based process sources such as, for example, inductively coupled plasma (ICP) sources, microwave sources, surface wave plasma sources, ECR plasma sources, and capacitively coupled (parallel plate) plasma sources.
As illustrated, each of the first process chamber 120 and second process chamber 130 includes a pair of processing stations in side-by-side arrangement so that a pair of workpieces can be simultaneously exposed to the same process. More particularly, the first process chamber 120 can include a first processing station 122 and a second processing station 124 in side-by-side arrangement. The second process chamber 130 can include a first processing station 132 and a second processing station 134 in side-by-side arrangement. Each processing station can include a workpiece support (e.g., a pedestal) for supporting a workpiece during processing. In some embodiments, each processing station can share a common pedestal with two portions for supporting a workpiece. In some embodiments, the workpiece support can include a pedestal assembly including a baseplate, an electrostatic chuck configured to support the workpiece and a replaceable part. The replaceable part can include a focus ring arranged relative to the electrostatic chuck such that at least a portion of the focus ring at least partially surrounds a periphery of the workpiece when the workpiece is positioned on the electrostatic chuck. The first process chamber 120 and/or the second process chamber 130 can be selectively sealed off from the transfer chamber 115 for processing.
The transfer chamber 115 can include a workpiece handling robot 150. The workpiece handling robot 150 can be configured to transfer workpieces from the workpiece column 110 in the loadlock chamber 114 to the processing stations in the first process chamber 120 and/or the second process chamber 130. The workpiece handling robot 150 can also transfer workpieces between the first process chamber 120 and the second process chamber 130.
As shown in
In some embodiments, the storage chamber 250 is a vacuum capable storage chamber capable of being maintained at the same vacuum as the transfer chamber 115. In certain other embodiments, the storage chamber 250 is configured such that it can be sealed off from the transfer chamber 115. The vacuum capable storage chamber can include one or more access doors configured to allow the workpiece handling robots to access replaceable parts in the storage chamber. For example, the access doors are large enough such that the workpiece handling robots can place a used replaceable part on a shelf within the storage chamber 250 and can remove a new replaceable part from one of the shelves. Accordingly, replaceable parts can be placed in or removed from the storage chamber 250 without breaking the vacuum of the overall system.
In some embodiments, the storage chamber 250 can include one or more access doors configured to allow for replacement of new or used replaceable parts from the atmospheric surrounding environment. For example, in certain embodiments the storage chamber 250 in communication with the transfer chamber 115 can be sealed off such that the transfer chamber 115 remains at a desired process pressure. The storage chamber 250 can then be accessed and serviced from the atmospheric environment such that used replaceable parts can be removed from the storage chamber 250 and new replaceable parts can be placed within the storage chamber 250. After service of the storage chamber 250 is complete, the storage chamber 250 can. be brought back to the desired process pressure utilizing any known system for establishing a process pressure within the storage chamber 250. Once at the desired process pressure is achieved, such as the same process pressure or vacuum as the transfer chamber 115, the storage chamber 250 can be unsealed from the transfer chamber 115 such that one or more of the workpiece handling robots can again access the storage chamber 250.
The workpiece handling robot 150 can be configured to transfer replaceable parts among the storage chamber 250 and the various processing stations for automated replacement of replaceable parts without breaking vacuum. For example, the workpiece handling robot 150 can be used to transfer replaceable parts from the first process chamber 120 or the second process chamber 130 to the storage chamber 250. The workpiece handling robot 150 can also be used to transfer replaceable parts from the storage chamber 250 to the first process chamber 120 or the second process chamber 130. In certain embodiments the workpiece handling robot 150 can retrieve a used replaceable part from one of the processing stations in the first process chamber 120 and/or second process chamber and transfer the used part to the storage chamber 250. The workpiece handling robot 150 can also retrieve a new replaceable part from the storage chamber 250 and transfer the new replaceable part to one of the processing stations of either the first process chamber 120 or the second process chamber 130.
The workpiece handling robot can be coupled a controller, such that the controller can be used to control the workpiece handling robot for transferring new or used replaceable parts to and from the storage chamber and process chambers 120 and 130. The controller can be configured to control motion of the workpiece handling robot 150 according to a robotic arm motion pattern 280 (shown in
Referring now to
The third process chamber 170 and the fourth process chamber 180 can be used to perform any of a variety of workpiece processing on the workpieces, such as vacuum anneal processes, thermal treatment process, surface treatment processes, dry strip processes, dry etch processes, deposition processes, and other processes. In some embodiments, one or more of the third process chamber 170 and the fourth process chamber 180 can include plasma based process sources such as, for example, inductively coupled plasma (ICP) sources, microwave sources, surface wave plasma sources, ECR plasma sources, and capacitively coupled (parallel plate) plasma sources. In particular embodiments, the focus rings can be used in plasma processing sources used to provide a direct ion plasma etch process.
As illustrated, each of the third process chamber 170 and fourth process chamber 180 includes a pair of processing stations in side-by-side arrangement so that a pair of workpieces can be simultaneously exposed to the same process. More particularly, the third process chamber 170 can include a first processing station 172 and a second processing station 174 in side-by-side arrangement. The fourth process chamber 180 can include a first processing station 182 and a second processing station 184 in side-by-side arrangement. Each processing station can include a workpiece support (e.g., a pedestal) for supporting a workpiece during processing. In some embodiments, each processing station can share a common pedestal with two portions for supporting a workpiece. In some embodiments, the workpiece support can include a pedestal assembly including a baseplate, an electrostatic chuck configured to support the workpiece and a replaceable part. The replaceable part can include a focus ring arranged relative to the electrostatic chuck such that at least a portion of the focus ring at least partially surrounds a periphery of the workpiece when the workpiece is positioned on the electrostatic chuck. In some embodiments, the third process chamber 170 and/or the fourth process chamber 180 can be selectively sealed off from the transfer chamber 115 for processing.
To transfer workpieces to the third process chamber 170 and second process chamber 180, the system 200 can further include a transfer position 162 and a second workpiece handling robot 190. The transfer position 162 can be a part of the transfer chamber 162 or can be a separate chamber. The transfer position 162 can include a support column 160 for supporting a plurality of workpieces in a stacked arrangement and/or side-by-side arrangement. For instance, the support column 160 can include a plurality of shelves configured to support workpieces in a stacked vertical arrangement. The first workpiece handling robot 150 can be configured to transfer workpieces from the workpiece column 110, the first process chamber 120, or the second process chamber 130 to the workpiece column 160 in the transfer position 162. A second workpiece handling robot 190 can be configured to transfer workpieces from the support column 160 in the transfer position 162 to the processing stations in the third process chamber 170 and/or the fourth process chamber 180. The workpiece handling robot 190 can also transfer workpieces from the third process chamber 170 to the fourth process chamber 180.
As shown in
To transfer replaceable parts between the first process chamber 120, second process chamber 130 and the storage chamber 250, the system 200 can utilize the second workpiece handling robot 190 to transfer new or used replaceable parts from the storage chamber 250 to the support column 160 in the transfer position 162. The transfer position 162 can be a part of the transfer chamber 162 or can be a separate chamber. The transfer position 162 can include a support column 160 for supporting a plurality of replaceable parts in a stacked arrangement. For instance, the support column 160 can include a plurality of shelves configured to support replaceable parts in a stacked vertical arrangement. Accordingly, in some embodiments, the support column 160 is configured such that it can support both workpieces and replaceable parts in a stacked arrangement. The first workpiece handling robot 150 can be configured to transfer replaceable parts from the support column 160 to the side-by-side processing stations 122 and 124 of the first process chamber 120 or the side-by-side processing stations 132 and 134 of the second process chamber 130. The second workpiece handling robot 190 can be configured to transfer replaceable parts from the support column 160 in the transfer position 162 to the side-by-side processing stations 172 and 174 in the third process chamber, the side-by-side processing stations 182 and 184 in the fourth process chamber 180, and/or the storage chamber 250.
For removing used replaceable parts or providing new replaceable parts to one or more processing stations, the workpiece handling robots 150 and 190 can utilize a robotic arm motion pattern. For example, a controller can be utilized to control the motions of end effector on the arm of the workpiece handling robots 150 and 190 to control the motion of the end effector when accessing a processing station to transfer a replaceable part. The workpiece handling robot 150 can utilize the robotic arm motion pattern to access the processing stations 122, 124, 132, and 134. The workpiece handling robot 190 can utilize the robotic arm motion pattern to access the processing stations 172, 174, 182, and 184.
The processing system 200 includes four process chambers 120, 130, 170, and 180 and can be configured to simultaneously process up to eight workpieces at a time. Additional process stations can be added in linear fashion to provide additional processing capability. For instance, a fifth process chamber can be added in linear arrangement with the third process chamber 170. A sixth process chamber can be added in linear arrangement with the fourth process chamber 180. An additional transfer position and workpiece handling robot can be used to transfer workpieces to and from the fifth and sixth process chambers. Additional processing chambers can be included by extending the processing system in linear fashion in this manner.
In certain embodiments, the workpiece storage chamber can be located at other locations within the processing system without deviating from the scope of the present disclosure. For instance, in some embodiments, the workpiece storage chamber could be located above or below a transfer position (e.g., transfer position 162 of processing system 200). In addition, one or more of the processing chambers of a workpiece processing system (e.g., processing stations 120, 130, 170 or 180 of processing system 200) can be replaced with a storage chamber for new and/or used replaceable parts according to example embodiments of the present disclosure.
In other embodiments, the storage chamber 250 can be located at other locations within the processing system without deviating from the scope of the present disclosure. For example, the storage chamber could be disposed on one or more of the process chambers 120, 130, 170, and/or 180. The storage chamber could also be located above or below a transfer position (e.g., transfer position 162 of processing system 200). In addition, one or more of the processing chambers of a workpiece processing system (e.g., processing stations 120, 130, 170 or 180 of processing system 200) can be replaced with a storage chamber for new and/or used replaceable parts according to example embodiments of the present disclosure.
In some embodiments, the transfer position can have an opening or aperture that passes all the way through the transfer position so that workpiece handling robots can transfer workpieces and or replaceable parts using a direct transfer between robots.
In some embodiments, alternative approaches to the delivery of replaceable parts in a workpiece processing system can be used without deviating from the scope of the present disclosure. For example, additional transfer mechanism (e.g., robots, shuttle mechanisms, multi-axis robotics) can be mounted to a process chamber to transfer replaceable parts into and out of the process chamber.
The robotic arm motion pattern 280 can include extending in a first direction for a first period of time, extending in a second direction generally lateral to the first direction for a second period of time, and extending in a third direction that is different from the first direction and second direction for a third period of time. As shown, the robotic arm motion pattern 280 can be utilized to place the end effector 500 into one of the processing stations 122 or 124.
In some embodiments the robotic arm motion pattern can include extending the end effector 500 in a first direction for a first period of time such that the end effector enters the processing chamber 120. Accordingly, in some embodiments, extending the end effector 500 in the first direction moves the end effector from the transfer chamber 115 into the process chamber 120, but does not place the end effector 500 within one of the side-by-side processing stations 122, 124. The end effector 500 can then be moved according to a second direction that is generally lateral to the first direction in order to place the end effector 500 within one of the side-by-side processing chambers 122, 124. As used herein, “generally lateral” or “lateral to” refers to within about 45° of perpendicular to the first direction. In some embodiments, the second direction can range from about 10° to about 70°, such as 20° to about 60°, such as 30° to about 50°, of perpendicular to the first direction. The end effector 500 can then be moved in a third direction to ensure proper placement of the end effector 500 in the processing station 122 such that retrieval of a used replaceable part can be accomplished. In some embodiments, the third direction can be within 30° or less of perpendicular to the first direction. In some embodiments, the end effector 500 can also be removed from the processing station 122 according to the same robotic arm motion pattern, For example, the end effector 500 can be retracted back into the transfer chamber 115 according to the same robotic arm motion pattern 280.
In certain embodiments, the end effector 500 can have a new replaceable part 165 thereon. For example, the end effector 500 can retrieve a new replaceable part 165 from either the support column 160 or the storage chamber 250. The end effector 500 having the new replaceable part 165 thereon can then place the new replaceable part 165 within the processing station 122 according to the example robotic arm motion pattern provided herein. For example, the end effector can be moved in a first direction for a first period of time to access the process chamber 120, moved in a second direction lateral to the first direction for a second period of time to access one of the side-by-side processing stations 122, and moved in a third direction different from the first direction and second direction for a third period of time in order to ensure proper placement of the new replaceable part 165 in one of the side-by-side processing stations 122, 124.
The robotic arm motion pattern 280 disclosed herein can be utilized by one or more workpiece handling robots of the system. For example, workpiece handling robots 150 and 190 can both be coupled to a controller capable of executing the robotic arm motion pattern 280 described herein. The robotic arm motion pattern 280 can be utilized by workpiece handling robots 150 and 190 to access any of the side-by-side processing stations 122, 124, 132, 134, 172, 174, 182, and 184 of the respective process chambers 120, 130, 170 and 180, disclosed herein.
In some embodiments, the workpiece handling robots can be configured to transfer workpieces and replaceable parts using a scissor motion. For example, the workpiece handling robot 150 can simultaneously transfer the workpieces from the workpiece column in the loadlock chamber 114 to the two side-by-side processing stations 122 and 124 in the first process chamber 120 using, for instance, a scissor motion. Similarly, the workpiece handling robot 150 can simultaneously transfer workpieces from the workpiece column 110 in the loadlock chamber 4 to the two side-by-side processing stations 132 and 134 in the second process chamber 130 using, for instance, a scissor motion. The workpiece handling robot 190 can simultaneously transfer the workpieces from the support column 160 in the transfer position 162 to the two side-by-side processing stations 172 and 174 in the third process chamber 170 using, for instance, a scissor motion. The workpiece handling robot 190 can simultaneously transfer the workpieces from the support column 160 in the transfer position 162 to the two side-by-side processing stations 182 and 184 in the fourth process chamber 180 using, for instance, a scissor motion.
In some embodiments, a controller can be configured to adjust motion of the end effector to transfer replaceable parts (e.g., focus rings) based at least in part data received from one or more sensors (e.g., sensors associated with automated wafer centering system). For instance, optical sensor(s) can be used to monitor the motion of a replaceable part during the motion pattern. To ensure the proper placement of the replaceable part, the control can adjust the motion pattern in real time as the workpiece handling robot is transferring the replaceable part to provide for proper placement of the replaceable part with reduced error.
In some embodiments, one or more sensors can be used to determine the position of a replaceable part after being transferred into a process chamber by the workpiece handling robot. The sensors can include, for instance, one or more optical sensors. A controller can be configured to control the workpiece handling robot to adjust the position of the replaceable part when sensor measurements indicate the replaceable part has been positioned incorrectly (e.g., not concentrically with the workpiece support).
At (302) the method can include removing a used replaceable part 165 from a processing station 122, 124, 132, 134, 172, 174, 182, or 184. The workpiece handling robot 150 can move the end effector 500 thereon from the transfer chamber 115 to the process chamber 120 and into the processing station 122 according to a robotic arm motion pattern. The robotic arm motion pattern can include extending the end effector 500 in a first direction for a first period of time, extending the end effector 500 in a second direction lateral to the first direction for a second period of time, and extending the end effector 500 in a third direction different from the first direction and the second direction for a third period of time. Once the end effector 500 is in correct placement within the processing chamber 122, the replaceable part can be placed on the end effector 500. In some embodiments, the end effector 500 can lift the replaceable part 165 from a raised location within the processing station 122. For example, a plurality of pins connected to a lifting mechanism can be used to raise the replaceable part 165 from its processing location to a raised position. Once in a raised position, the end effector 500 can easily be placed under the replaceable part 165 for lifting the replaceable part 165 from the one or more pins.
Once the replaceable part 165 is placed on the end effector 500, the end effector 500 can be retracted back into the transfer chamber 115 via the robotic arm motion pattern, For example, the end effector 500 having the used replaceable part 165 thereon can be retracted according to a third direction different from the first direction and second direction for a third period of time, retracted according to a second direction lateral to the first direction for a second period of time, and retracted according to a first direction for a first period of time until the end effector 500 having the replaceable part 165 thereon is located back within the transfer chamber 115.
At (304) the method includes transferring the replaceable part to the storage chamber. Transferring the replaceable part 165 to the storage chamber 250 can include utilizing the workpiece handling robot 150 to place the used replaceable part 165 on the support column 160 in the transfer position 162. For example, the used replaceable part 165 can be placed on one of the shelves 161 located in the support column 160 in a stacked arrangement. The workpiece handling robot 190 can then remove the used replaceable part 165 from the shelf 161 from the support column 160 and transfer the replaceable part 165 to the storage chamber 250. The workpiece handling robot 190 can place the used replaceable part 165 on one of the shelves located within the storage chamber 250.
At (306) the method includes removing a new replaceable part from the storage chamber. The workpiece handling robot 190 can remove a new replaceable part 165 from one of the shelves in the storage chamber 250 and place the new replaceable part on one of the shelves 161 within the support column 160 in the transfer position 162 in a stacked arrangement.
At (308) the method includes transferring the new replaceable part to a processing station. Once the new replaceable part 165 is placed on one of the shelves 161 in the support column 160, workpiece handling robot 150 can access the support column 160 to remove the new replaceable part 165. Workpiece handling robot 150 can then be utilized to place the new replaceable part inside one of the side-by-side processing stations according to the robotic arm motion pattern. For example, the workpiece handling robot 150 can move the end effector 500 having the new replaceable part 165 thereon from the transfer chamber 115 to the process chamber 120 and into the processing station 122 according to a robotic arm motion pattern. The robotic arm motion pattern can include extending the end effector 500 in a first direction for a first period of time, extending the end effector 500 in a second direction lateral to the first direction for a second period of time, and extending the end effector 500 in a third direction different from the first direction and the second direction for a third period of time. Once the end effector 500 is in correct placement within the processing chamber 122, the new replaceable part 165 can be deposited within the processing station in any suitable manner. For example, in one embodiment, the replaceable part 165 (e.g. focus ring) can be placed on a plurality of pins in a raised position. Once securely placed on the pins, the pins can be lowered to place the replaceable part in a desired location within the processing station 122, such that further workpiece processing can be accomplished.
Once the replaceable part 165 is placed within the processing station 122, the end effector can be retracted back into the transfer chamber 115 via the robotic arm motion pattern 280. For example, the end effector 500 can be retracted according to a third direction different from the first direction and second direction for a third period of time, retracted according to a second direction lateral to the first direction for a second period of time, and retracted according to a first direction for a first period of time until the end effector 500 is located back within the transfer chamber 115.
In some embodiments, the workpiece handling robot can remove a test workpiece from the storage location. The test workpiece can be transferred to the processing station. A test process can be performed with the test workpiece. Data collected during the test process and/or characteristics of the test workpiece can be monitored to determine proper placement of the replaceable part.
Advantageously, the method (300) can be performed to allow for the automated replacement of replaceable parts without having to break vacuum of the processing system. Further, the method (300) allows for replacement of replaceable parts utilizing workpiece handling robots that are capable of transferring both workpieces and replaceable parts that are larger than the workpieces. Also, the robotic arm motion pattern allows for the end effector of the workpiece handling robot to enter one of the side-by-side processing stations, such that a replaceable part can be replaced.
At (402), the method includes transferring a plurality of workpieces to a workpiece column in a loadlock chamber. For instance, a plurality of workpieces can be transferred from a front end portion of processing system to a workpiece column 110 in a loadlock chamber 114. The workpieces can be transferred to the workpiece column 110, for instance, using one or more robots associated with the front end portion of the processing system.
At (404) the method includes using a workpiece handling robot to transfer workpieces from the workpiece column to the processing stations in the first process chamber and/or second process chamber. For instance, the workpiece handling robot 150 can transfer two workpieces to processing station 122 and processing station 124 respectively in process chamber 120.
At (406) the method includes performing a first treatment process on the plurality of workpieces in the first process chamber and/or second process chamber. The first treatment process can include, for instance, an anneal process, a thermal treatment process, a surface treatment process, a dry strip processes, a dry etch process, a deposition process or other process.
At (408), the method can include transferring, with the workpiece handling robot a plurality of workpieces to a transfer position. Workpiece handling robot 150 can transfer two workpieces to processing station 122 and processing station 124 respectively in process chamber 120. In some embodiments, the workpiece handling robot 150 can transfer workpieces to a workpiece column 160 located at a transfer position 162,
At (410), the method can include transferring, with a second workpiece handling robot 190 disposed in the transfer chamber, the plurality of workpieces from the transfer position to at least two processing stations in a third process chamber and/or fourth process chamber. The third process chamber can be disposed in linear arrangement with the first process chamber and. the fourth process chamber can be disposed in linear arrangement with the second process chamber. For instance, workpiece handling robot 190 can transfer two workpieces from workpiece column 160 in the transfer position 162 to processing station 172 and processing station 174 respectively in process chamber 170.
At (412) the method can include performing a second treatment process on the plurality of workpieces in the third process chamber and/or fourth process chamber. The third treatment process can include, for instance, an anneal process, a thermal treatment process, a surface treatment process, a dry strip processes, a dry etch process, a deposition process or other process.
At (414), the method can include transferring, by the workpiece handling robot 190, the plurality of workpieces back to the transfer position. For instance, workpiece handling robot 190 can transfer workpieces from the process chamber 170 and/or the process chamber 180 to a workpiece column 160 located at the transfer position 162.
At (416), the method can include transferring the processed workpieces back to the workpiece column in the loadlock chamber. For instance, workpiece handling robot 150 can transfer two workpieces from the first process chamber 120 and/or the second process chamber 130. In some embodiments, workpiece handling robot 150 can transfer two workpieces from the transfer position 162 to the workpiece column in the loadlock chamber. One or more robots located in a front end of the processing system can then transfer to processed workpieces to, for instance, a cassette.
As shown, (404)-(416) can be repeated according to the number of workpieces desired for processing. After the desired number of workpieces have been processed or another trigger condition occurs, the method can include replacing replaceable parts (418) in the processing stations. For example, replaceable parts, such as focus rings, can need to be replaced after exposure to a certain number of processing treatments. Replacing the replaceable parts (418) can be accomplished by way of method 300 provided herein. Accordingly, the present systems and methods allow for the automated processing of workpieces and the automated replacement of replacement parts without having to break the vacuum or alter the process pressure of the system.
Turning now to
As shown in
In general, the end effector 500 can be configured to separately support workpieces and replaceable parts, where the workpieces have a different diameter than the replaceable parts. For example, as shown in
In one embodiment, such as the embodiment shown in
The support elements SE1, SE2 are spaced apart such that the first support elements SE1 can only support workpieces and such that the second support elements SE2 can only support focus rings. For instance, in
In some embodiments, the second support elements SE2 on the spatula portion 510 are positioned closer to the distal end 506 of the end effector 500 than the first support elements SE1 on the spatula portion 510. Similarly, in one embodiment, the second support elements SE2 on the arm portion 508 are positioned closer to the proximal end 504 of the end effector 500 than the first support elements SE1 on the arm portion 508.
Further, in some embodiments, the first support elements SE1 on the spatula portion 510 are positioned further from the longitudinal axis 502 than the second support elements SE2 on the spatula portion 510. For instance, the first support elements SE1 on the spatula portion 510 are spaced apart from the axis 502 by a first distance L1 in a direction generally perpendicular to the axis 502, and the second support elements SE2 on the spatula portion 510 are spaced apart from the axis 502 by a second distance L2 in the direction generally perpendicular to the axis 502, where the first distance L1 is greater than the second distance L2.
In another embodiment, such as the embodiment shown in
Similar to
As described above, in some embodiments, the second support elements SE2 on the spatula portion 510 are positioned closer to the distal end 506 of the end effector 500 than the first support elements SE1 on the spatula portion 510. Similarly, in one embodiment, the second contact area CA2 is positioned closer to the proximal end 504 of the end effector 500 than the first contact area CAI of the shared support element CSE1 on the arm portion 508,
Further, in some embodiments, the first support elements SE1 on the spatula portion 510 are positioned further from the longitudinal axis 502 than the second support elements SE2 on the spatula portion 510. For instance, the first support elements SE1 on the spatula portion 510 are spaced apart from the axis 502 by a first distance L1 in a direction generally perpendicular to the axis 502, and the second support elements SE2 on the spatula portion 510 are spaced apart from the axis 502 by a second distance L2 in the direction generally perpendicular to the axis 502, where the first distance L1 is greater than the second distance L2.
Alternatively, in some embodiments, such as the embodiment shown in
The embodiment of the end effector 500 shown in
Referring now to
As described above, a workpiece processing system (e.g., system 100, 200) includes a workpiece support(s) (e.g., station 122, 124, 132, 134) within a process chamber (e.g., 120, 130, 170, 180) that is configured to support a workpiece (e.g., workpiece 113, 163) during a process treatment step(s). As shown in
The focus ring adjustment assembly 600 includes a plurality of pins for supporting the focus ring. instance, as shown in
In one embodiment, as shown in
In some embodiments, the focus ring has three backside radial slots to receive the pin(s) 602. This configuration can fix the position of the focus ring 165A, allowing for accurate centering of the focus ring on to the pedestal and can also prevent lateral movement. The backside radial slots can also allow for thermal expansion of the focus ring while being supported by the pins 602. In some embodiments, the focus ring can include a backside annular groove. The backside annular groove extends annularly around the backside surface of the focus ring. The backside annular groove can include an outer diameter and an inner diameter. The pin(s) 602 may be configured to contact the outer diameter. During thermal expansion of the focus ring, the pin(s) 602 may no longer contact the outer diameter but my slide radially in the groove in a direction towards the inner diameter to accommodate thermal expansion of the focus ring.
In some embodiments, as shown in
Additionally, or alternatively, in some embodiments, the shape of the groove G1 of the focus ring 165B, the shape of the pin(s) 602, or both are configured such that rotation of the pin(s) 602 secures or fixes the focus ring 165B to the pin(s) 602. For instance, rotation of the pin(s) 602 through a predetermined locking angle can fix the focus ring 165B to the pin(s) 602.
A top down view of a suitable pin support plate is shown in
The pin support plate 606 is configured to be actuated between a lowered position and one or more raised positions such that the focus ring 165 is respectively moved between processing position to one or more raised positions. For instance, as shown in
The pin support plate 606 is movable, as will be described in greater detail below, into its raised position shown in
As shown in
The focus rings 165 can be configured to be installed in the chamber with a particular azimuthal orientation relative to the workpiece support. Typically, the focus rings 165 are positioned in a storage chamber (e.g., storage chamber 250) to have the proper azimuthal orientation when removed from the storage chamber for installation within the process chamber. However, in some embodiments, it is desirable to further adjust the azimuthal position of the focus rings 165. In such embodiments, the storage chamber and/or end effector for moving the focus rings 165 can include one or more features for adjusting an azimuthal position of a focus ring 165.
Referring now to
In some implementations, the plasma processing apparatus 700 can include a plurality of inductive elements, such as a primary inductive element 730 and a secondary inductive element 740, for generating an inductive plasma in the interior space 702. The primary inductive element 730 and the secondary inductive element 740 can each include a coil or antenna element that when supplied with. RF power, induces a plasma in the process gas in the interior space 702 of the processing chamber 701. For instance, a first RF generator 760 can be configured to provide electromagnetic energy through a matching network 762 to the primary inductive element 730. A second RF generator 770 can be configured to provide electromagnetic energy through a matching network 772 to the secondary inductive element 740.
While the present disclosure makes reference to a primary inductive element and a secondary inductive element, those of ordinary skill in the art, should appreciate that the terms primary and secondary are used for convenience purposes only. The secondary coil can be operated independently of the primary coil. The primary coil can be operated independently of the secondary coil. In addition, in some embodiments, the plasma processing apparatus can only have a single inductive coupling element.
In some implementations, the plasma processing apparatus 700 can include a metal shield 752 disposed around the secondary inductive element 740. In this manner, the metal shield 752 separates the primary inductive element 730 and the secondary inductive element 740 to reduce cross-talk between the primary inductive element 730 and the secondary inductive element 740.
In some implementations, the plasma processing apparatus 700 can include a first Faraday shield 754 disposed between the primary inductive element 730 and the dielectric window 710. The first Faraday shield 754 can be a slotted metal shield that reduces capacitive coupling between the primary inductive element 730 and the process chamber 701. As illustrated, the first Faraday shield 754 can fit over the angled portion of the dielectric window 710.
In some implementations, the metal shield 752. and the first Faraday shield 754 can form a unitary body 750 for ease of manufacturing and other purposes. The multi-turn coil of the primary inductive element 730 can be located adjacent the first Faraday shield 754 of the unitary body 750. The secondary inductive element 740 can be located proximate the metal shield 752 of the unitary body 750, such as between the metal shield 752 and the dielectric window 710.
The arrangement of the primary inductive element 130 and the secondary inductive element 140 on opposite sides of the metal shield 752 allows the primary inductive element 730 and secondary inductive element 740 to have distinct structural configurations and to perform different functions. For instance, the primary inductive element 730 can include a multi-turn coil located adjacent a peripheral portion of the process chamber 701. The primary inductive element 730 can be used for basic plasma generation and reliable start during the inherently transient ignition stage. The primary inductive element 730 can be coupled to a powerful RF generator and expensive auto-tuning matching network and can be operated at an increased RF frequency, such as at about 13.56 MHz. As used herein, the term “about” refers to a range of values within 20 percent of a stated numerical value.
In some implementations, the secondary inductive element 740 can be used for corrective and supportive functions and for improving the stability of the plasma during steady state operation. Furthermore, since the secondary inductive element 740 can be used primarily for corrective and supportive functions and improving stability of the plasma during steady state operation, the secondary inductive element 740 does not have to be coupled to as powerful an RF generator as the primary inductive element 730 and can therefore be designed differently and cost effectively to overcome the difficulties associated with previous designs. As discussed in detail below, the secondary inductive element 740 can also be operated at a lower frequency, such as at about 2 MHz, allowing the secondary inductive element 740 to be very compact and to fit in a limited space on top of the dielectric window.
In some implementations, the primary inductive element 730 and the secondary inductive element 740 can be operated at different frequencies. The frequencies can be sufficiently different to reduce cross-talk in the plasma between the primary inductive element 730 and the secondary inductive element 740. For instance, the frequency applied to the primary inductive element 730 can be at least about 1.5 times greater than the frequency applied to the secondary inductive element 740. In some embodiments, the frequency applied to the primary inductive element 730 can be about 13.56 MHz and the frequency applied to the secondary inductive element 740 can be in the range of about 1.75 MHz to about 2.15 MHz. Other suitable frequencies can also be used, such as about 400 kHz, about 4 MHz, and about 27 MHz. While the present disclosure is discussed with reference to the primary inductive element 730 being operated at a higher frequency relative to the secondary inductive element 740, those of ordinary skill in the art, using the disclosures provided herein, should understand that the secondary inductive element 740 could be operated at the higher frequency without deviating from the scope of the present disclosure.
In some implementations, the secondary inductive element 740 can include a planar coil 742 and a magnetic flux concentrator 744. The magnetic flux concentrator 744 can be made from a ferrite material. Use of a magnetic flux concentrator with a proper coil can give high plasma coupling and good energy transfer efficiency of the secondary inductive element 740 and can significantly reduce its coupling to the metal shield 752. Use of a lower frequency, such as about 2 MHz, on the secondary inductive element 740 can increase skin layer, which also improves plasma heating efficiency.
in some implementations, the primary inductive element 730 and the secondary inductive element 740 can carry different functions. For instance, the primary inductive element 730 can be used to carry out the basic functions of plasma generation during ignition and providing enough priming for the secondary inductive element 740. The primary inductive element 730 can have coupling to both plasma and the grounded shield to stabilize plasma potential. The first Faraday shield 754 associated with the primary inductive element 730 avoids window sputtering and can be used to supply the coupling to the grounded shield.
Additional coils can be operated in the presence of good plasma priming provided by the primary inductive element 730 and as such, preferably have good plasma coupling and good energy transfer efficiency to plasma. A secondary inductive element 740 that includes a magnetic flux concentrator 744 provides both a good transfer of magnetic flux to plasma volume and at the same time a good decoupling of the secondary inductive element 740 from the surrounding metal shield 752. The magnetic flux concentrator 744 and symmetric driving of the secondary inductive element 740 further reduces the amplitude of the voltage between coil ends and surrounding grounded elements. This can reduce sputtering of the dome, but at the same time gives some small capacitive coupling to plasma, which can be used to assist ignition. In some implementations, a second Faraday shield can be used in combination with this secondary inductive element 740 to reduce capacitive coupling of the secondary inductive element 740.
In some implementations, the plasma processing apparatus 700 can include a radio frequency (RF) bias electrode 760 disposed within the processing chamber 701. The plasma processing apparatus 700 can further include a ground plane 770 disposed within the processing chamber 701 such that the ground plane 770 is spaced apart from the RF bias electrode 760 along the vertical direction V. As shown, the RF bias electrode 760 and the ground plane 770 can, in some implementations, be disposed within the pedestal 704.
In some implementations, the RF bias electrode 760 can be coupled to a RF power generator 780 via a suitable matching network 782. When the RF power generator 780 provides RF energy to the RF bias electrode 760, a plasma can be generated from a mixture in the processing chamber 701 for direct exposure to the substrate 706. In some implementations, the RF bias electrode 760 can define a RF zone 762 that extends between a first end 764 of the RF bias electrode 760 and a second end 766 of the RF bias electrode 760 along the lateral direction L. For instance, in some implementations, the RF zone 762 can span from the first end 764 of the RF bias electrode 760 to the second end 766 of the RF bias electrode 760 along the lateral direction L. The RF zone 762 can further extend between the RF bias electrode 760 and the dielectric window 710 along the vertical direction V.
It should be understood that a length of the ground plane 770 along the lateral direction L is greater than a length of the RF bias electrode 760 along the lateral direction L. In this manner, the ground plane 770 can direct RF energy towards emitted by the RF bias electrode 760 towards the substrate 706.
Referring now to
As shown, the lift pin 810 can be positioned outside of the RF zone 762 defined by the RF bias electrode 760. Furthermore, the lift pin 810 can penetrate the ground plane 770. For instance, in some implementations, the lift pin 810 can extend through an opening defined by the ground plane 770. It should be understood that locating the lift pin 810 outside of the RF zone 762 and additionally having the lift pin 810 penetrate the ground plane 770 can reduce arcing risks associated with applying RF power (e.g. bias power) from the RF power generator 780 to the RF bias electrode 760 during a plasma process. Furthermore, interference (e.g., electrical and mechanical) between the lift pin 810 and the focus ring 790 can be reduced.
In some implementations, the focus ring adjustment assembly 800 can include an actuator 820 configured to move the lift pin 810 along the vertical direction V to facilitate movement of the focus ring 790 between at least the first position (
More particularly,
The cassette 1000 includes one or more includes a base plate 1400 and two vertical datum plates 1402a, 1402b mounted opposite from each other on the base plate 1400. While, two vertical datum plates are shown, the disclosure is not so limited, indeed, any number of datum plates 1402 can be utilized. For example, in certain embodiments a single datum plate 1402 can be employer, while in other embodiments three or more datum plates 1402 can be utilized. The datum plates 1402a, 140b each have a plurality of shelves 1410 thereon. one or more replaceable parts 1300 can be place between two shelves 1410 disposed on datum plates 1402a, 1402b. Depending on the size of the cassette 1000 and the storage chamber 1002 any number of shelves 1410 can be mounted to the datum plates 1402. For example, in certain embodiments the cassette 1000 includes at least five shelves, such as at least six shelves, such as at least 7 shelves, etc. Furthermore, the shelves 1410 can be configured to be any shape or size as needed to store the replaceable part 1300. For example, as shown, the replacement part 1300 includes one or more focus rings 1302. Given the nature of the focus ring, the shelves 1410 do not fully extend from one vertical datum plate 1402a to the other 1402b. As such, in embodiments, the shelves 1410 include a pair of fins extending from datum plates 1402a, 1402b, and the shelves 1410 do not fully extend between the datum plates 1402a, 1402b. However, in other embodiments where the replacement part 1300 requires additional support, the shelves 1410 can include a continuous shelf that fully extends from one vertical datum plate 1402a to the other 1402b.
As shown in
A divider 1500 is disposed beneath the shelves 1410 in the z-direction. Additional shelves 1412 and 1414 are disposed beneath the divider 1500 in the z-direction. Shelf 1412 is configured to hold a workpiece (e.g., semiconductor wafer), while shelf 1414 is configured to hold a pedestal cover. The divider 1500 can section off the replacement part shelves 1410 from the workpiece shelf 1412 and the pedestal cover shelf 1414. The divider 1500 separates the replaceable parts 1300 from the stored workpiece, which can help maintain cleanliness of the semiconductor during storage in the cassette 1000. As shown, shelves 1412, 1414 do not include raised pins and instead include raised platforms 1416 disposed thereon for facilitating storage of the workpiece and pedestal cover. Additional buffer shelves can be disposed between the divider 1500 and shelves 1410. (Not shown).
The cassette 1000 also includes a brace 1460 mounted between the two vertical datum plates 1402a, 1402b. One end of the brace 1460 can be mounted to a top surface of vertical datum plate 1402a, while a second end of the brace 1460 can be mounted to a top surface of vertical datum plate 1402b. The brace 1460 can include features or be formed of materials that strengthen the cassette 1000. As shown, the brace 1460 includes two rods 1462, 1464 that run from vertical datum plate 1402a to vertical datum plate 1402b to provide additional strength to the overall structure and framework of the cassette 1000.
The cassette(s) 1000 as provided herein can be formed from any suitable materials, especially those configured for use in semiconductor processing apparatuses. Further, because semiconductor processing can include a variety of pressures and temperatures, the cassette 1000 provided herein is configured to be operable at a wide variety of pressures and temperatures. For instance, the cassette 1000 can be operable for use in pressure ranges between vacuum and atmospheric pressure. The cassette 1000 can be operable at temperatures of about 50° C. or less. In embodiments, the cassette 1000 does not include a power assisted actuator or a pneumatic actuator.
At 2002, the method 2000 can include receiving a storage cassette 1000 into a storage chamber 1002 of a workpiece processing platform. For instance, the cassette 1000 can be placed in the interior 1012 of the housing 1010 of the storage chamber. The cover 1016 can be opened in order to allow for access to the interior 1012 of the housing 1010. The storage cassette 100, including cassette cover 1200, can be loaded into position in the interior 1012 of the storage chamber 1002. Once placed, the cassette cover 1200 can be removed to allow for access to the contents of the cassette 1000. The cover 1016 can then be placed in a closed condition to seal the storage chamber.
At 2004, the method includes obtaining a pedestal cover from the storage cassette. The storage cassette is vertically actuated to a first vertical position such that the shelf 1414 holding the pedestal cover is in alignment with the slit 1602 in the storage chamber 1002. An end effector 1610 can then be used to retrieve the pedestal cover 1470 from the storage cassette 1000. For instance, the end effector 1610 enters the storage chamber 1002 through slit 1602 and remove the pedestal cover 1470 from shelf 1414 on the cassette 1000.
At 2006, the method includes placing the pedestal cover 1470 on a pedestal of a processing station in the workpiece processing system. For instance, the system includes a workpiece handling robot having an arm with an end effector 1610. The end effector 1610 can be moved within the system 100 according to multiple directional movements. For instance, when it is time to remove the pedestal cover 1470 from the cassette 1000 and place it on a pedestal in a processing station, the end effector 1610 can move into one of the processing stations according to a robotic arm motion pattern described herein (e.g., robotic arm motion pattern 280). The robotic arm motion patterns disclosed herein can be utilized by one or more workpiece handling robots of the system. For example, workpiece handling robots 150 and 190 can both be coupled to a controller capable of executing the robotic arm motion pattern 280 described herein. The robotic arm motion pattern 280 can be utilized by workpiece handling robots 150 and 190 to access any of the side-by-side processing stations 122, 124, 132, 134, 172, 174, 182, and 184 of the respective process chambers 120, 130, 170 and 180, disclosed herein.
At 2008. the method can include obtaining a used replaceable part 1300a (e.g., focus ring) from a processing station. The end effector 1610 can be moved into the processing station according to the robotic arm motion pattern in order to grab the used replaceable part 1300 disposed therein. Once the end effector 1610 is in correct placement within the processing chamber 122, a used replaceable part 1300a can be placed on the end effector 1610. In some embodiments, the end effector 1610 can lift the used replaceable part 1300a from a raised location within the processing station. For example, a plurality of pins connected to a lifting mechanism can be used to raise the used replaceable part 1300a from its processing location to a raised position. Once in a raised position, the end effector 1610 can easily be placed under the used replaceable part 1300a for lifting the used replaceable part 1300a from the one or more pins.
Once the used replaceable part 1300a is placed on the end effector 1610, the end effector 1610 can be retracted back into the transfer chamber 115 via the robotic arm motion pattern. The used replaceable part 1300a can then be transferred back to the cassette 1000 located in the storage chamber 1002. Transferring the used replaceable part 1300a back to the cassette 1000 can include vertically actuating the cassette 1000 to a second vertical position such that one or more shelves 1410, configured to hold replaceable parts, are in alignment with the slit 1602 of the storage chamber 1002. Once in second vertical position, the end effector 1610 can utilize a suitable robotic arm motion pattern to place the used replacement part 1300a on the shelf 1410 of the cassette 1000.
At 2010, the method includes obtaining a clean replaceable part 1300b from the cassette 1000 and placing the clean replaceable part 1300b in the processing station. Obtaining a clean replaceable part 1300b from the cassette 1000 includes utilizing the vertical actuator 1600 to move the cassette 1000 to a third vertical position within the storage chamber 1002. In third vertical position, a shelf 1410 holding a clean replacement part 1300b is in alignment with the slit 1602 in the storage chamber 1002 such that the end effector 1610 can move into the storage chamber 1002 to retrieve a clean replaceable part 1300b from one of the shelves 1410 therein. For instance, a robotic arm pattern can be used to move the end effector 1610 into correct placement in the storage chamber 1002 and then also to retract the end effector 1610 to place it in correct placement in one of the processing chambers. The end effector 1610 can then place the clean replacement part 1300b into position on one or more of a plurality of raised pins located within the processing chamber. Once placed on the pins, the pins can be lowered with a lifting mechanism, in order to lower the clean replaceable part 1300a into place in the processing station. The end effector 1610 can be retracted back into the transfer chamber via the robotic arm motion pattern.
At 2012, the method includes obtaining the pedestal cover 1470 from the processing station and placing it back into the storage cassette 1000. For example, the end effector 1610 can enter the processing station and retrieve the pedestal cover 1470. For instance, the end effector 1610 can be placed under the pedestal cover 1470 in order to remove the pedestal cover 1470 from the pedestal in the processing station. The end effector 1610 can then be retracted back into the transfer chamber via a suitable robotic arm motion pattern. The storage cassette 1000 is then vertically actuated back to the first vertical position such that the pedestal cover shelf 1414 is in alignment with the slit 1602 of the storage chamber 1002. The end effector 1610 can then move into the storage chamber 1002 to place the pedestal cover 1470 on pedestal cover shelf 1414 on the cassette 1000. Once the pedestal cover 1470 is properly places on the pedestal cover shelf 1414, the end effector 1610 can be removed from the storage chamber 1002.
At 2014, the method includes obtaining a test workpiece 1471 from the storage cassette 1000 and placing the test workpiece 1471 in the processing station. Obtaining a test workpiece 1471 from the cassette 1000 includes utilizing the vertical actuator 1600 to move the cassette 1000 to a fourth vertical position within the storage chamber 1002. In fourth vertical position, a shelf 1412 holding a test workpiece 1471 is placed in alignment with the slit 1602 in the storage chamber 1002 such that the end effector 1610 can move into the storage chamber 1002 to retrieve the test workpiece 1471 from shelf 1412 therein. For instance, a robotic arm motion pattern can be used to move the end effector 1610 into correct placement in the storage chamber 1002 and then also to retract the end effector 1610 from the storage chamber 1002. The end effector 1610 can then move the test workpiece 1471 into placement in one of the processing chambers. Once in the processing chamber, the end effector 1610 can place the test workpiece 1471 onto one of the pedestals therein.
At 2016, the method includes performing one or more test processes in the processing station. For instance, additional test processes can be performed with the test workpiece 1471. Data collected during the test process and/or characteristics of the test workpiece 1471 can be monitored to determine proper placement of the replaceable part. One or more sensors can be used to monitor test parameters or test workpiece 1471 characteristics in order to provide data regarding the proper placement of the replaceable part. Accordingly, one or more sensors are configured to facilitate determining a position of a replaceable part in the process chamber.
At 2018, the method includes returning the test workpiece 1471 to the storage cassette 1000. The end effector 1610 enters the processing station and retrieves the test workpiece 1471 from the pedestal therein. Once the test workpiece 1471 is placed on the end effector 1610, the end effector 1610 can be retracted back into the transfer chamber 115 via a robotic arm motion pattern. The test workpiece can then be transferred back to the cassette 1000 located in the storage chamber 1002. The end effector 500 can utilize a robotic arm motion pattern to place the test workpiece 1471 on the shelf 1412 of the cassette 1000.
While the present subject matter has been described in detail with respect to specific example embodiments thereof, it will be appreciated that those skilled in the art, upon attaining an understanding of the foregoing can readily produce alterations to, variations of, and equivalents to such embodiments. Accordingly, the scope of the present disclosure is by way of example rather than by way of limitation, and the subject disclosure does not preclude inclusion of such modifications, variations and/or additions to the present subject matter as would be readily apparent to one of ordinary skill in the art.
The present application claims the benefit of priority to U.S. Provisional Application No. 63/276,764, filed Nov. 8, 2021, and U.S. Provisional Application No. 63/317,611 filed Mar. 8, 2022, both of which are incorporated by reference herein.
| Number | Date | Country | |
|---|---|---|---|
| 63317611 | Mar 2022 | US | |
| 63276764 | Nov 2021 | US |
