Embodiments of the present invention generally relate to a ring and ring assembly for an etching or other plasma processing chamber.
In semiconductor processing chambers, substrates undergo various processes such as deposition, etching and annealing. During some of the processes, the substrate is placed onto a substrate support such as an electrostatic chuck (ESC), for processing. In an etch process a ring may be placed around the substrate to prevent erosion of the areas of the substrate support that are not covered by the substrate. The ring focuses the plasma and positions the substrate in place.
Rings are usually made of quartz or silicon based material and are highly consumed in the etch process as they are exposed to etching gases and/or fluids. The rings are etched by the plasma during wafer processing and eventually begin to erode. The erosion of the rings leads to process drift after sufficient material removed from the ring changes the profile of the processing plasma along the edge of substrate. The process drift ultimately leads to defects on the substrates. The rings that are significantly eroded are usually replaced to ensure process conformity and prevent the manufacturing defects from affecting processing yields. However, replacing the rings requires the manufacturing process equipment to be shutdown which is expensive. There is a tradeoff of between shutting down the manufacturing process to replace the rings prior to generating defects and significantly reducing the service life of the ring and lowering manufacturing yields.
Thus, there is a need in the art monitoring the manufacturing process and extending yields.
The present invention generally relates method and apparatus for detecting erosion to a ring assembly used in an etching or other plasma processing chamber. In one embodiment, a method begins by obtaining a metric indicative of wear on a ring assembly disposed on a substrate support in a plasma processing chamber prior to processing with plasma in the plasma processing chamber. The metric for the ring assembly is monitored with a sensor. A determination is made if the metric exceeds a threshold and generating a signal in response to the metric exceeding the threshold.
So that the manner in which the above recited features of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.
In a processing chamber used for semiconductor manufacturing, edge rings are used as part of the process kit surrounding the wafer/substrate. The substrate sits on top of a pedestal or an electrostatic chuck which usually has a step feature for installation of the edge ring. The edge ring is used to control the process performance on the substrate in the processing chamber. Monitoring degradation or erosion of the edge ring permits the edge ring to be replaced prior to the processing performance drifting out of specification. Contemporary methods of monitoring edge ring erosion are empirically determined. Embodiments disclosed below provide active or in-situ monitoring of the edge ring erosion over time (RF hours) to limit or prevent the process drift from exceeding allowable thresholds. This allows semiconductor manufacturers to implement scheduled preventative maintenance accurately and to optimize the life of the process kits in the chambers without sacrificing performance.
The body 128 of the processing chamber 100 may have sidewalls 103, a lid 184 and a bottom surface 109. The sidewalls 103, lid 184 and bottom surface 109 define an interior volume 116. The interior volume 116 of the processing chamber 100 is a high vacuum vessel that is coupled through a throttle valve (not shown) to a vacuum pump 134. In operation, the substrate is placed on the substrate support 115 and the chamber interior is pumped down to a near vacuum environment.
A showerhead 120 is disposed proximate the lid 184 and within the interior volume 116. One or more gases are introduced from a gas panel 160 via the showerhead 120 into the interior volume 116 of the processing chamber 100. The showerhead 120 may be coupled to an RF power source 132 through a matching network 124. The gas from the showerhead 120 may be ignited into a plasma 118 in the interior volume 116 by applying the power from the RF power source 132 to the showerhead 120. The plasma may be used to etch a feature in a substrate 144 during processing and then pumped out of the processing chamber 100 through the vacuum pump 134.
The substrate support 115 is disposed below the showerhead 120, which is used to supply various gases into the interior volume 116 of the processing chamber 100. The substrate support 115 generally includes an electrostatic chuck (ESC) 102, a ring assembly 170 having a cover ring 104 and an edge ring 105, a cathode 106 to electrically bias the ESC 102, an insulator pipe 108, a pedestal insulator 110, and a pedestal support 112.
The insulator pipe 108 and the pedestal insulator 110 function to electrically isolate the chamber walls and the substrate support 115, respectively, from the electrical bias applied to the ESC 102. The substrate support 115 may be biased by a DC power supply 152. An RF power source 126 may optionally be coupled to the substrate support 115 through a matching network 122.
The cover ring 104 may be a single piece ring that rests on the edge ring 105 and insulator pipe 108. The substrate 144, when placed onto the substrate support 115, will rest on the ESC 102 and be surrounded by the edge ring 105 and cover ring 104. Since the edge ring 105 and cover ring 104 also focuses the plasma, the edge ring 105 and cover ring 104 are usually made of silicon or quartz and consumed during processing. In one embodiment, the cover ring 104 is formed from a quartz material and the edge ring 105 has a body 190. The body 190 is formed from a silicon containing material. In plasma etch chambers, the cover ring 104 and edge ring 105 protects the ESC 102 from erosion by the plasma as well as controlling the distribution of the plasma near the edge of the substrate 144 during processing. To prevent process drift due to erosion of the cover ring 104 and edge ring 105, the edge ring 105 and or processing chamber 100 incorporates structures for monitoring the wear of the edge ring 105.
Variations for monitoring the wear on the edge ring 105 are disclosed here as separate embodiments.
The body 190 of the edge ring 105 has a top surface 201 exposed to the plasma environment of the processing chamber 100. The body 190 of the edge ring 105 has a bottom surface 206. The bottom surface 206 of the edge ring 105 is disposed on the ESC 102. The body 190 additionally has a wear indicator material 290 embedded therein. For example, the wear indicator material 290 may be a pin 205 or slug of material, a layer of material, or other feature different than the material of the body 190 and suitable to detect as the edge ring 105 is worn by plasma. The wear indicator material 290 may be formed from a material different than the body 190 and having detectable different properties. For example, the wear indicator material 290 may have a reflectivity different than the body 190.
In the embodiment of
The pin 205 may be placed in the bottom surface 206 of the edge ring by mechanical or chemical techniques. For example, a hole may be formed in the bottom surface 206 of the edge ring 105 and the pin 205 may be inserted therein. The pin 205 may be adhered therein or pressed fit therein. Optionally, the pin 205 may be covered over with an additional layer of material for the edge ring 105 such as a sheet of silicon or by a deposition of silicon to cover the pin 205 and form the bottom surface 206 of the edge ring 105. Alternately, the pin 205 may be formed in the edge ring 105 using plasma processing techniques or 3D printing. The pin 205 is a layer of material different than the material of the body 190 of the edge ring 105 positioned at a predetermined depth from the top surface 201 of the edge ring 105 that will get exposed and detected as erosion of the top surface 201 occurs. For example, the pin 205, or wear indicator material 290, may be formed from quartz while the edge ring 105 is formed from a silicon containing material such as SiC.
A sensor 230 may be positioned above the edge ring 105. The edge ring may have an alignment feature. The alignment feature may be a key, pin, or other suitable device for orienting the edge ring 105 with the sensor 230. The sensor 230 may be attached to the showerhead 120. In one embodiment, the sensor 230 is disposed in the showerhead 120. The sensor 230 may have a line of sight 232 focused on the pin 205 (or said location) in the edge ring 105. The sensor 230 may be coupled via an optical or electrical transmission line 231 to the controller 180. The sensor 230 may be configured to operate in the absence of plasma, i.e., while processing of the substrate 144 is not occurring. Alternatively, the sensor 230 may be disposed outside of the chamber 100 looking through a window at the edge ring 105.
During processing, the edge ring 105 is eroded by the plasma.
In
The body 190 of the edge ring 105 has a top surface 301 exposed to the plasma 118 in the processing chamber 100. The edge ring 105 has a bottom surface 306. The bottom surface 306 of the edge ring is disposed on the ESC 102. The body 190 of the edge ring 105 additionally has a signal spike material 310 embedded therein. As will be discussed below, the signal spike material 310, when eroded by the plasma, may introduce particles into the interior volume 116 detectable by a sensor 350. The signal spike material 310 may be in the shape of a plug or annular ring having an upper surface 311 disposed nearest the top surface 301 of the edge ring 105. The signal spike material 310 has a lower surface 356 disposed nearest the bottom surface 306 of the edge ring 105. The lower surface 356 of the signal spike material 310 may extend to the bottom surface 306 of the edge ring 105 such that the bottom surface 306 of the edge ring 105 is substantially coplanar with the lower surface 356 of the signal spike material 310. Alternately, the lower surface 356 of the signal spike material 310 may be disposed between the top surface 301 and bottom surface 306 of the edge ring 105. In one embodiment, the signal spike material 310 is fully encapsulated by the edge ring 105. In a second embodiment, the lower surface 356 of the signal spike material 310 is accessible along or through an opening in the bottom surface 306 of the edge ring 105.
The signal spike material 310 may be placed in the bottom surface 306 of the edge ring by mechanical or chemical techniques. For example, a hole may be formed in the bottom surface 306 of the edge ring 105 and the signal spike material 310 may be inserted therein. The signal spike material 310 may be adhered therein or pressed fit therein. Optionally, the signal spike material 310 may be covered over with an additional layer of material for the edge ring 105 such as a sheet of silicon or by a deposition of silicon to cover the signal spike material 310 and form the bottom surface 306 of the edge ring 105. Alternately, the signal spike material 310 may be formed in the edge ring 105 using plasma processing techniques or 3D printing. The signal spike material 310 is a layer of material different than the material of the body 190 of the edge ring 105 positioned at a predetermined depth from the top surface 301 of the edge ring 105 that will get exposed and detected as erosion of the top surface 301 occurs. For example, the signal spike material 310 may be formed from SiO, a florescence material, or other suitable material which emits photons when eroded by the plasma 118.
The sensor 350 may be disposed in the interior volume 116. In one embodiment, the sensor 350 is attached to the showerhead 120. In another embodiment, the sensor is attached to the body 128 of the processing chamber 100. The sensor 350 may detect particles in the chamber environment, i.e., interior volume 116. The sensor 350 may detect emissions from the plasma processing such as erosion of the silicon in the edge ring 105, particles in the plasma 118, as well as the signal spike material 310. The sensor 350 may be coupled via an optical or electrical transmission line to the controller 180. The sensor 230 may be configured to operate in the presence of plasma, i.e., while processing is occurring on the substrate 144. The sensor 230 may be a spectrometer that detects changes in plasma properties, a laser that activates the material that will get exposed after erosion, a capacitance measurement sensor if placed in ESC, an ion-selective electrode, or other suitable device.
During processing, the body 190 of the edge ring 105 is eroded by the plasma.
In
The body 190 of the edge ring 105 has a top surface 401 exposed to the plasma 118 in the processing chamber 100. The body 190 has a bottom surface 406. The body 190 additionally has an inner edge 462 adjacent to the substrate 144 and an outer edge 464 opposite the inner edge 462. The bottom surface 406 of the body 190 of the edge ring 105 is disposed on the ESC 102. The body 190 has a first layer 410 which encompasses the top surface 401. The first layer 410 is disposed on the signal spike layer 420. The material and function of the signal spike layer 420 is substantially similar to that of the signal spike material 310 discussed in
Each of the signal spike layer 420, the first layer 410 and optionally third layer 430 extend from the inner edge 462 to the outer edge 464 of the edge ring 105. The signal spike layer 420 has an upper surface 421 upon which the first layer 410 is disposed upon. The signal spike layer 420 has a lower surface 422 in contract with either the ESC 102 in some embodiments, or the third layer 430 in other embodiments.
The signal spike layer 420 may be formed through mechanical techniques, such sintering or bonding. The signal spike layer 420 may alternately be formed through chemical techniques, such as depositing silicon to cover the signal spike layer 420 with the first layer 410 and optionally the third layer 430 of the body 190 of the edge ring 105. Alternately, the signal spike layer 420 may be formed by 3D printing the edge ring 105 or portions thereof. The signal spike layer 420 is a layer of material different than the material of the body 190 of the edge ring 105 positioned at a predetermined depth from the top surface 401 of the body 190 that will get exposed and detected as erosion of the top surface 401 occurs. For example, the signal spike layer 420 may be formed from SiO, a florescence material, or other suitable material which would emit photons when eroded by the plasma 118.
The sensor 350 may be disposed in the interior volume 116. In one embodiment, the sensor 350 is attached to the showerhead 120. In another embodiment, the sensor is attached to the body 128 of the processing chamber 100. The sensor 350 is substantially described with relation to
During processing, the body 190 of the edge ring 105 is eroded by the plasma.
The body 190 of the edge ring 105 has a top surface 501 exposed to plasma 118 in the interior volume 116 of the processing chamber 100. The body 190 has a bottom surface 506. The bottom surface 506 of the edge ring 105 is disposed on the ESC 102. The body 190 is formed from an insulative material such as SiC.
An electrode 530 may be disposed in the ESC 102 and positioned below the edge ring 105. The electrode 530 may be coupled via an optical or electrical transmission line to the controller 180. The electrode 530 may operate analogously as a continuous wave or digitally with discrete stepping waves. The electrode 530 may operate to measure the resistance of the edge ring 105 by coupling with the plasma 118, i.e., while processing of the substrate 144 is occurring, or other time when plasma is present within the interior volume 116.
During processing, the top surface 501 of the body 190 of the edge ring 105 is eroded by the plasma.
In
The body 190 of the edge ring 105 has a top surface 601 exposed to the interior volume 116 of the processing chamber 100. The body 190 has a bottom surface 606. The bottom surface 606 of the edge ring 105 is disposed on the ESC 102. The body 190 of the edge ring 105 may be formed from SiC, quartz or other suitable materials.
A sensor 630 may be disposed in the ESC 102 and positioned below the edge ring 105. The sensor 630 may be coupled via an optical or electrical transmission line to the controller 180. The sensor 630 may be a microphone for detecting acoustical signals. Alternately, the sensor 630 may be an optical light detector. The sensor 630 may operate to measure the thickness of the edge ring 105. In embodiments where the sensor 630 is a microphone for detecting acoustical signals, accurate measurement of the edge ring can be performed without additional filtering when the plasma, i.e., plasma 118, is not making noise.
During processing, the top surface 601 of the body 190 of the edge ring 105 is eroded by the plasma.
In
The embodiments disclosed above advantageously provide a methodology for providing process feedback and timing preventative maintenance prior to experiencing unacceptable process drift which may result in substrate defects. The embodiments ensure maximum use of the ring assembly prior to replacement thus reducing expensive and unwarranted replacements. Additionally, certain embodiments, such as the electrode, may be utilized to provide real-time feedback of process and allow tuning of the process.
While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
This application is a continuation of U.S. patent application Ser. No. 16/518,940, filed Jul. 22, 2019 which is a divisional of U.S. patent application Ser. No. 15/679,040, filed Aug. 16, 2017 which claims benefit of U.S. Provisional Application Ser. No. 62/378,492, filed Aug. 23, 2016, each of which are herein incorporated by reference in their entirety.
Number | Date | Country | |
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62378492 | Aug 2016 | US |
Number | Date | Country | |
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Parent | 15679040 | Aug 2017 | US |
Child | 16518940 | US |
Number | Date | Country | |
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Parent | 16518940 | Jul 2019 | US |
Child | 18201698 | US |