Examples of the present disclosure generally relate to apparatuses for processing substrates, such as semiconductor substrates. More particularly, a process kit and methods for use thereof, are disclosed.
In the processing of substrates, such as semiconductor substrates and display panels, a substrate is placed on a support in a process chamber while suitable process conditions are maintained in the process chamber to deposit, etch, form layers on, or otherwise treat surfaces of the substrate. During etching processes, a plasma, which drives the etching process, may not be uniformly distributed across the substrate surface. The non-uniformity is particularly apparent at the edge of the substrate surface. This non-uniformity contributes to poor processing results. Thus, some process chambers use edge rings, which may also be referred to as a process kit ring, in order to increase plasma uniformity and improve process yield.
However, traditional edge rings erode over time. As the edge ring erodes, plasma uniformity across the substrate surface decreases, thereby negatively affecting substrate processing. Since there is a direct correlation between plasma uniformity and the quality of processed substrates, traditional process chambers require frequent replacement of edge rings to maintain plasma uniformity. However, the frequent replacement of edge rings results in undesirable downtime for preventative maintenance, and leads to increased costs for consumable components such as the edge rings.
Therefore, there is a need in the art for methods and apparatuses that improve plasma uniformity.
Apparatuses including a height-adjustable edge ring and methods for use thereof are described herein. In one example, a process kit for processing a substrate is provided. The process kit has a support ring comprising an upper surface having a radially inner edge disposed at a first height and a radially outward edge disposed at a second height less than the first height, the radially inner edge having a greater thickness than the radially outward edge. An edge ring is disposed on the support ring, an inner surface of the edge ring interfaced with the radially inner edge of the support ring. A cover ring is disposed radially outward of the edge ring, the edge ring independently moveable relative to the support ring and the cover ring. One or more push pins are disposed radially inward of an inner diameter of the cover ring, the one or more push pins being operable to elevate the edge ring, wherein movement in a radial direction of the support ring is constrained by the one or more push pins.
So that the manner in which the above recited features of the present disclosure can be understood in detail, a more particular description of the disclosure, briefly summarized above, may be had by reference to aspects of the disclosure, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical aspects of this disclosure and are therefore not to be considered limiting of its scope, for the disclosure may admit to other equally effective aspects.
To facilitate understanding, identical reference numerals have been used, wherever possible, to designate identical elements that are common to the Figures. Additionally, elements of one example may be advantageously adapted for utilization in other examples described herein.
Apparatuses including a height-adjustable edge ring, and methods for use thereof are described herein. In one example, a substrate support assembly includes a height-adjustable edge ring, and the substrate support assembly is located within a process chamber. The substrate support assembly includes an electrostatic chuck, an edge ring positioned on a portion of the electrostatic chuck, and one or more actuators to adjust the height of the edge ring via one or more push pins. The height-adjustable edge ring can be used to compensate for erosion of the edge ring over time. In addition, the height-adjustable edge ring can be removed from the process chamber via a slit valve opening without venting and opening the process chamber. The height-adjustable edge ring can be tilted by the one or more actuators in order to improve azimuthal uniformity at the edge of the substrate.
The substrate support assembly 111 includes one or more electrodes 153 coupled to a bias source 119 through a matching network 120 to facilitate biasing of the substrate 109 during processing. The bias source 119 may illustratively be a source of up to about 1000 W (but not limited to about 1000 W) of RF energy at a frequency of, for example, approximately 13.56 MHz, although other frequencies and powers may be provided as desired for particular applications. The bias source 119 may be capable of producing either or both of continuous or pulsed power. In some examples, the bias source 119 may be a DC or pulsed DC source. In some examples, the bias source 119 may be capable of providing multiple frequencies. The one or more electrodes 153 may be coupled to a chucking power source 160 to facilitate chucking of the substrate 109 during processing. The substrate support assembly 111 may include a process kit (not shown) surrounding the substrate 109. Various embodiments of the process kit are described below.
The inductively coupled plasma apparatus 102 is disposed above the lid 103 and is configured to inductively couple RF power into the process chamber 100 to generate a plasma within the process chamber 100. The inductively coupled plasma apparatus 102 includes first and second coils 110, 112, disposed above the lid 103. The relative position, ratio of diameters of each coil 110, 112, and/or the number of turns in each coil 110, 112 can each be adjusted as desired to control the profile or density of the plasma being formed. Each of the first and second coils 110, 112 is coupled to an RF power supply 108 through a matching network 114 via an RF feed structure 106. The RF power supply 108 may illustratively be capable of producing up to about 4000 W (but not limited to about 4000 W) at a tunable frequency in a range from 50 kHz to 13.56 MHz, although other frequencies and powers may be utilized as desired for particular applications.
In some examples, a power divider 105, such as a dividing capacitor, may be provided between the RF feed structure 106 and the RF power supply 108 to control the relative quantity of RF power provided to the respective first and second coils. In some examples, the power divider 105 may be incorporated into the matching network 114.
A heater element 113 may be disposed atop the lid 103 to facilitate heating the interior of the process chamber 100. The heater element 113 may be disposed between the lid 103 and the first and second coils 110, 112. In some examples, the heater element 113 may include a resistive heating element and may be coupled to a power supply 115, such as an AC power supply, configured to provide sufficient energy to control the temperature of the heater element 113 within a desired range.
During operation, the substrate 109, such as a semiconductor wafer or other substrate suitable for plasma processing, is placed on the substrate support assembly 111 and process gases supplied from a gas panel 116 through entry ports 117 into the inner volume of the chamber body 101. The process gases are ignited into a plasma 118 in the process chamber 100 by applying power from the RF power supply 108 to the first and second coils 110, 112. In some examples, power from a bias source 119, such as an RF or DC source, may also be provided through a matching network 120 to electrodes 153 within the substrate support assembly 111. The pressure within the interior of the process chamber 100 may be controlled using a valve 121 and a vacuum pump 122. The temperature of the chamber body 101 may be controlled using liquid-containing conduits (not shown) that run through the chamber body 101.
The process chamber 100 includes a controller 155 to control the operation of the process chamber 100 during processing. The controller 155 comprises a central processing unit (CPU) 123, a memory 124, and support circuits 125 for the CPU 123 and facilitates control of the components of the process chamber 100. The controller 155 may be one of any form of general-purpose computer processor that can be used in an industrial setting for controlling various chambers and sub-processors. The memory 124 stores software (source or object code) that may be executed or invoked to control the operation of the process chamber 100 in the manner described herein.
The facilities plate 228 is positioned above a lower portion of the ground plate 226 and between the insulating plate 227 and the electrostatic chuck 229. The electrostatic chuck 229 may include a plurality of electrodes 153 (four are shown) embedded in an insulating material 236. The electrodes 153 are coupled to the chucking power source 160 (shown in
The first edge ring 242 is positioned on the electrostatic chuck 229. The first edge ring 242 surrounds and abuts the radially-outward edges of the substrate 109. The first edge ring 242 facilitates protection of the edges of the substrate 109 during processing, and additionally, provides lateral support to the substrate 109 during processing. The first edge ring 242 may be stationary with respect to the substrate 109 during processing.
The second edge ring 244 is positioned over and radially outward of the first edge ring 242. The radially-outward edge 202 of the second edge ring 244, as well as a bottom surface 204 of the second edge ring 244, is in contact with a cover ring 246. The second edge ring 244 is positioned concentrically with respect to the first edge ring 242 and the substrate 109. The second edge ring 244 assists the first edge ring 242 in providing the substrate 109 with lateral support and reducing undesired etching or deposition of material at the radially-outward edges of the substrate 109.
The substrate support assembly 111 may also include one or more actuators 247 (one is shown), such as a stepper motor or linear actuator, among others. In one example, the one or more actuators 247 are disposed in the ground plate 226. It is contemplated, however, that the actuator 247 may be positioned externally of the substrate support assembly 111. Each actuator 247 is adapted to engage, or interface with, one or more push pins 248. The one or more push pins 248 extend from the ground plate 226, through the facilities plate 228 and the sleeve 230, and into contact with the cover ring 246. Actuation of the one or more push pins 248 results in vertical actuation, or displacing, of the cover ring 246 and the second edge ring 244 relative to an upper surface of the substrate 109 and/or the first edge ring 242. It is contemplated that the first edge ring 242 may be omitted in some aspects. The position of the second edge ring 244 may be adjusted to a height which accommodates for erosion of the second edge ring 244 in order to increase plasma uniformity across a substrate surface during processing.
One or more bellows (shown in
In one example, the first edge ring 242 may be fabricated from silicon. In one example, the second edge ring 244 may be fabricated from silicon. In a particular example, the second edge ring 244 may be fabricated from silicon carbide (SiC). In one example, the one or more actuators 247 are micro-stepper motors. In another example, the one or more actuators 247 are piezo-electric motors. In one example, the one or more push pins 248 are fabricated from quartz or sapphire. In one example, the controller may be a general purpose computer that includes memory for storing software. The software may include instructions for detecting erosion of the second edge ring 244 and then directing the one or more actuators 247 to raise the one or more push pins 248 such that the second edge ring 244 is elevated to a desired height.
The process kit 304 includes a first edge ring 342, a second edge ring 344, and a cover ring 346. The first edge ring 342 is positioned adjacent to the radially outward edges of the substrate 109 to reduce undesired processing effects at the edge of the substrate 109. The second edge ring 344 is positioned radially outward of and above the first edge ring 342. The second edge ring 344 may be positioned radially inward of and above the cover ring 346. In a lowermost position, the second edge ring 344 may have a lower surface 302 in contact with one or more of the first edge ring 342, the sleeve 230, and the cover ring 346. In the lowermost position, the second edge ring 344 may share a coplanar upper surface with the cover ring 346. The substrate support assembly 311 may be similar to the substrate support assembly 111; however, the one or more push pins 248 are positioned to contact the second edge ring 344. The second edge ring 344 may be fabricated from the same material as the second edge ring 244. The one or push pins 248 actuate the second edge ring 344 directly, rather than indirectly via actuation of the cover ring 346. In such an example, the cover ring 346 remains stationary during height adjustment of the second edge ring 344. The substrate support assembly 311 may be used in place of the substrate support assembly 111.
The substrate support assembly 311 includes a height-adjustable edge ring assembly 349 including one or more actuators 247, one or more push pins 248, and the second edge ring 344. The edge ring assembly 349 may be similar to the edge ring assembly 249; however, the one or more push pins 248 of the edge ring assembly 349 are positioned through the vertical walls of the ground plate 226 and through the cover ring 346. Thus, the push pins 248 of the edge ring assembly 349 do not travel through the insulating plate 227 and the sleeve 230, eliminating the bores formed through the insulating plate 227 and the sleeve 230. Moreover, because the edge ring assembly 349 actuates the second edge ring 344 and allows the cover ring 346 to remain stationary, the substrate support assembly 311 may reduce particle generation due to a reduced number of moving parts. The first edge ring 342 may be fabricated from the same material as the first edge ring 242.
The substrate support assembly 411 includes a height-adjustable edge ring assembly 449. The edge ring assembly 449 includes one or more actuators 247, one or more push pins 248, and the second edge ring 444. The one or more actuators 247 actuate the one or more push pins 248 to elevate the second edge ring 444 relative to an upper surface of the substrate 109, as well relative to the first edge ring 442 and the cover ring 446. Similar to the substrate support assembly 311, the cover ring 446 remains stationary while the second edge ring 444 is elevated. Due to a reduced number of movable components, there is a reduced likelihood of particle generation during processing. However, unlike the substrate support assembly 311, the push pins 248 of the substrate support assembly 411 are disposed through the insulating plate 227 and the sleeve 418. The one or more push pins 248 contact a lower surface 404 of the second edge ring 444 to transfer movement from the actuator 247 to the second edge ring 444. In one example, the first edge ring 442 may be fabricated from silicon. In one example, the second edge ring 444 may be fabricated from silicon. In a particular example, the second edge ring 444 may be fabricated from silicon carbide (SiC).
The method 550 begins at operation 552. In operation 552, a first number of substrates of substrate are processed. While processing the first number of substrates, a top surface 602 of an edge ring 644 is coplanar with a top surface 604 of the substrate 109, as shown in
After processing the first number of substrates, the edge ring 644 may be eroded as shown in
Accordingly, in operation 554, the edge ring 644 is elevated from a first position above an edge ring 642 to a second position above the edge ring 642 based on a first amount of erosion of the edge ring 644. The edge ring 642 may be the first edge ring 242, 342, 442. The edge ring 644 may be the second edge ring 244, 344, 444. The edge ring 644 is elevated to maintain a linear plasma sheath 662 (i.e., maintain the plasma sheath 662 to be parallel to the top surface 604 of the substrate 109), as shown in
Alternatively, instead of detecting the amount of erosion on the edge ring 644, the edge ring 644 may be adjusted after an empirically-determined number of substrates are processed. Alternatively, the edge ring 644 may be adjusted in response to a measurement of plasma sheath deformation.
In operation 556, a second number of substrates are processed while maintaining the edge ring 644 in the adjusted position. While in the adjusted position, the edge ring 644 positions the plasma sheath 662 in a coplanar orientation with the top surface 604 of the substrate 109. After processing a second number of substrates, the method 550 may further include detecting a second amount of erosion of the edge ring 644 and elevating the edge ring 644 from the second position to a third position. The distance between the second position and the third position may be about 0.05 millimeters to about 5 millimeters. The operations of method 550 may be repeated as more substrates are processed and further erosion of the edge ring 644 occurs.
The process kit 703 includes a support ring 730, an edge ring 732, and a cover ring 734. The support ring 730 is disposed on the second surface 722 of the second portion 720 of the electrostatic chuck 712, and the support ring 730 surrounds the first portion 716 of the electrostatic chuck 712. The support ring 730 may be fabricated from silicon or SiC. The support ring 730 may be positioned concentrically with respect to the first portion 716 of the electrostatic chuck 712. The support ring 730 may have an inner radius that is less than 100 microns greater than a radius of the first portion 716 of the electrostatic chuck 712. The edge ring 732 may be disposed on the support ring 730, and the edge ring 732 may be made of silicon, SiC, or other suitable material. The edge ring 732 may be positioned concentrically with respect to the first portion 716 of the electrostatic chuck 712. The cover ring 734 may be disposed on the sleeve 724 and the cover ring 734 may surround the edge ring 732 and the support ring 730.
The substrate support assembly 700 further includes one or more actuators 736 (one is shown), such as a stepper motor, one or more pin holders 737 (one is shown), one or more bellows 735 (one is shown), and one or more push pins 733 (one is shown). The push pins 733 may be fabricated from quartz, sapphire, or other suitable material. Each pin holder 737 is coupled to a corresponding actuator 736, each bellows 735 surrounds a corresponding pin holder 737, and each push pin 733 is supported by a corresponding pin holder 737. Each push pin 733 is positioned through an opening formed in each of the ground plate 704, the insulating plate 706, and the sleeve 724. One or more push pin guides, such as the push pin guides 239 shown in
After processing a certain number of substrates inside of the process chamber 100, the edge ring 732 may erode, and the first surface 814 is not coplanar with a processing surface of a substrate, such as the substrate 802, disposed on the first portion 716 of the electrostatic chuck 712. The edge ring 732 may be lifted by the one or more push pins 733, such as three push pins 733, in order for the first surface 814 of the edge ring 732 to be coplanar with the processing surface of the substrate 802 disposed on the first portion 716 of the electrostatic chuck 712. Thus, the edge ring 732 may be supported by the one or more push pins 733 during processing. Since the radial clearance of each push pin 733 inside of the openings 806, 812 is small, the movement of the edge ring 732 in the horizontal, or radial, direction is constrained as the edge ring 732 is supported by the one or more push pins 733. Because the movement of the edge ring 732 in the horizontal, or radial, direction is constrained, the edge ring 732 is consistently positioned concentrically with respect to the first portion 716 of the electrostatic chuck 712. Since the substrate 802 is positioned concentrically with respect to the first portion 716 of the electrostatic chuck 712, the edge ring 732 is also consistently positioned concentrically with respect to the substrate 802 when the edge ring 732 is supported either by the support ring 730 or by the one or more push pins 733. Having the edge ring 732 consistently positioned concentrically with respect to the substrate 802 and the first surface 814 of the edge ring 732 being coplanar with the processing surface of the substrate 802 improves plasma uniformity across the processing surface of the substrate during processing.
Sometimes the substrate may suffer from an azimuthal non-uniformity near the edge of the substrate. In order to adjust the azimuthal edge process results, the edge ring 732 may be tilted by the one or more actuators 736 via the one or more push pins 733. The one or more actuators 736 may raise the one or more push pins 733 to different elevations, and the edge ring 732 is tilted with respect to the processing surface of the substrate 802. By titling the edge ring 732, i.e., causing the edge ring 732 to be non-coplanar with the processing surface of the substrate 802, the plasma sheath and/or chemistry in a specific location near the substrate edge is changed, and the azimuthal non-uniformity near the substrate edge is reduced.
In order to lift the edge ring 732 while the edge ring 732 is coplanar with the processing surface of the substrate 802, the one or more actuators 736 may be calibrated so the one or more push pins 733 are raised by the actuators 736 to the same elevation. One method of calibrating the actuators 736 is to slowly raise each push pin 733 until the person calibrating the actuators 736 feels each push pin 733 is slightly above the first surface 718 of the first portion 716 of the electrostatic chuck 712. Another method of calibrating the actuators 736 is to use an acoustic sensor to hear the contact of the push pins 733 against the edge ring 732, to use an accelerometer on the edge ring 732 to sense the contact, or to look at the servo position feedback (following error or servo torque) to sense the contact.
Another benefit of being able to raise the edge ring 732 is that the edge ring 732 can be raised to a high enough elevation such that a vacuum robot blade (not shown) can enter the process chamber via a slit valve beneath the edge ring 732 and remove the edge ring 732 from the process chamber without venting and opening the process chamber. The edge ring 732 may be removed from the process chamber by the vacuum robot after a number of substrates have been removed from the process chamber. A new edge ring 732 may be placed in the process chamber by the vacuum robot. The new edge ring 732 may be made of a different material or may have a different shape, in order to optimize results of a specific process. In addition, the ability to transfer edge ring 732 in and out of the process chamber without venting and opening the process chamber enables the process chamber to run longer between wet clean cycles which are expensive and cause lost productivity.
An exemplary process sequence for removing the edge ring 732 starts with lifting the edge ring 732 to an elevation above a substrate transfer plane by the one or more push pins 733, extending the vacuum robot blade into the process chamber at a location below the edge ring 732, lowering the edge ring 732 onto the vacuum robot blade by the one or more push pins 733, moving the vacuum robot blade with the edge ring 732 disposed thereon out of the process chamber and into a loadlock chamber (not shown), picking the edge ring 732 off of the vacuum robot blade by raising the loadlock chamber lift (not shown) or lowering the vacuum robot blade, venting the loadlock chamber, using a factory interface robot (not shown) to remove the edge ring 732 from the loadlock chamber, and putting the edge ring 732 in a storage location (the storage location could have multiple locations holding different or similar edge rings).
The support ring 850 may be tightly fitted between the second portion 807 of the electrostatic chuck 803 and the one or more protrusions 842 of the cover ring 840. The cover ring 840 may include a top surface 862, a first surface 864 opposite the top surface 862, a second surface 866 opposite the top surface 862, a third surface 868 opposite the top surface 862, and a fourth surface 870 opposite the top surface 862. The first surface 864 may be in contact with and supported by the support ring 850, while a gap is formed between surfaces 866, 868 and the sleeve 724 and between the surface 870 and the shield 728. The cover ring 840 may further include a fifth surface 872 connecting surfaces 866, 868 and a sixth surface 874 connecting surfaces 864, 866. Each cavity 844 of the one or more cavities of the sleeve 724 may include a first surface 876 and a second surface 878 opposite the first surface 876. Gaps formed between the first surface 876 and the fifth surface 872 and between the second surface 878 and the sixth surface 874 may be small, such as 0.01 in or less, which constrains the movement of the cover ring 840 in the horizontal, or radial, direction. Since the support ring 850 is tightly fitted between the sixth surface 874 of the cover ring 840 and the second portion 807 of the electrostatic chuck 803, the movement of the support ring 850 in the horizontal, or radial, direction is also constrained. The edge ring 852 may be consistently positioned concentrically with respect to the substrate (not shown) when the edge ring 852 is either supported by the second surface 809 of the electrostatic chuck 803 or by the one or more push pins 733. The edge ring 852 may be removed from the process chamber by the same method as removing the edge ring 732.
Examples of the present disclosure result in increased plasma uniformity across the surface of a substrate being processed in a process chamber. Since there is a direct correlation between plasma uniformity and process yield, the increased plasma uniformity leads to an increase in process yield. Furthermore, process chambers making use of the present disclosure experience less downtime for preventative maintenance by extending the usable life of edge rings.
While the foregoing is directed to examples of the present disclosure, other and further examples of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
Number | Date | Country | Kind |
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201641019009 | Jun 2016 | IN | national |
This application is a continuation of and claims benefit of U.S. patent application Ser. No. 15/399,809, filed on Jan. 6, 2017, U.S. Provisional Patent Application Ser. No. 62/287,038, filed on Jan. 26, 2016, and Indian Provisional Application No. 201641019009, filed on Jun. 2, 2016, each of which is herein incorporated by reference in its entirety.
Number | Date | Country | |
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62287038 | Jan 2016 | US |
Number | Date | Country | |
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Parent | 15399809 | Jan 2017 | US |
Child | 17843652 | US |