| Patent application number | Description | Published |
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| 20090084169 | WAFER BOW METROLOGY ARRANGEMENTS AND METHODS THEREOF - An arrangement for quantifying a wafer bow. The arrangement is positioned within a plasma processing system is provided. The arrangement includes a support mechanism for holding a wafer. The arrangement also includes a first set of sensors, which is configured to collect a first set of measurement data for a plurality of data points on the wafer. The first set of measurement data indicates a minimum gap between the first set of sensors and the wafer. The first set of sensors is positioned in a first location, which is outside of a set of process modules of the plasma processing system. | 04-02-2009 |
| 20090084758 | METHOD AND APPARATUS FOR SHAPING GAS PROFILE NEAR BEVEL EDGE - A method for etching a bevel edge of a substrate in a processing chamber is provided. The method includes flowing an inert gas into a center region of the processing chamber defined above a center region of the substrate and flowing a mixture of an inert gas and a processing gas over an edge region of the substrate. The method further includes striking a plasma in the edge region, wherein the flow of the inert gas and the flow of the mixture maintain a mass fraction of the processing gas substantially constant. A processing chamber configured to clean a bevel edge of a substrate is also provided. | 04-02-2009 |
| 20090113656 | Apparatus for isolated bevel edge clean and method for using the same - An apparatus, system and method for cleaning a substrate edge include a bristle brush unit that cleans bevel polymers deposited on substrate edges using frictional contact in the presence of cleaning chemistry. The bristle brush unit is made up of a plurality of outwardly extending vanes and is mounted on a rotating shaft. An abrasive material is distributed throughout and within the outwardly extending vanes of the bristle brush unit to provide the frictional contact. The bristle brush unit cleans the edge of the substrate by allowing frictional contact of the plurality of abrasive particles with the edge of the substrate in the presence of fluids, such as cleaning chemistry, to cut, rip and tear the bevel polymer from the edge of the substrate. | 05-07-2009 |
| 20090114244 | EDGE ELECTRODES WITH VARIABLE POWER - The embodiments provide structures and mechanisms for removal of etch byproducts, dielectric films and metal films on and near the substrate bevel edge, and chamber interior to avoid the accumulation of polymer byproduct and deposited films and to improve process yield. In an exemplary embodiment, a plasma processing chamber configured to clean a bevel edge of a substrate is provided. The plasma processing chamber includes a bottom electrode configured to receive the substrate, wherein the bottom electrode is coupled to a radio frequency (RF) power supply. The plasma processing chamber also includes a top edge electrode surrounding an insulating plate opposing the bottom electrode. The top edge electrode is electrically grounded. The plasma processing chamber further includes a bottom edge electrode surrounding the bottom electrode. The bottom edge electrode opposes the top edge electrode. The top edge electrode, the substrate disposed on the bottom electrode, and the bottom edge electrode are configured to generate a cleaning plasma to clean the bevel edge of the substrate. The bottom edge electrode and the bottom electrode are electrically coupled to one another through an RF circuit tunable to adjust the amount of RF current going between the substrate disposed on the bottom electrode, the bottom edge electrode and the top edge electrode. | 05-07-2009 |
| 20090166326 | EDGE ELECTRODES WITH DIELECTRIC COVERS - The embodiments provide apparatus and methods for removal of etch byproducts, dielectric films and metal films near the substrate bevel edge, and chamber interior to avoid the accumulation of polymer byproduct and deposited films and to improve process yield. In an exemplary embodiment, a plasma processing chamber configured to clean a bevel edge of a substrate is provided. The plasma processing chamber includes a substrate support configured to receive the substrate. The plasma processing chamber also includes a bottom edge electrode surrounding the substrate support. The bottom edge electrode and the substrate support are electrically isolated from one another by a bottom dielectric ring. A surface of the bottom edge electrode facing the substrate is covered by a bottom thin dielectric layer. The plasma processing chamber further includes a top edge electrode surrounding a top insulator plate opposing the substrate support. The top edge electrode is electrically grounded. A surface of the top edge electrode facing the substrate is covered by a top thin dielectric layer. The top edge electrode and the bottom edge electrode oppose one another and are configured to generate a cleaning plasma to clean the bevel edge of the substrate. | 07-02-2009 |
| 20090170334 | Copper Discoloration Prevention Following Bevel Etch Process - A method of bevel edge etching a semiconductor substrate having exposed copper surfaces with a fluorine-containing plasma in a bevel etcher in which the semiconductor substrate is supported on a semiconductor substrate support comprises bevel edge etching the semiconductor substrate with the fluorine-containing plasma in the bevel etcher; evacuating the bevel etcher after the bevel edge etching is completed; flowing defluorinating gas into the bevel etcher; energizing the defluorinating gas into a defluorination plasma at a periphery of the semiconductor substrate; and processing the semiconductor substrate with the defluorination plasma under conditions to prevent discoloration of the exposed copper surfaces of the semiconductor substrate upon exposure, the discoloration occurring upon prolonged exposure to air. | 07-02-2009 |
| 20090188627 | GAS MODULATION TO CONTROL EDGE EXCLUSION IN A BEVEL EDGE ETCHING PLASMA CHAMBER - The various embodiments provide apparatus and methods of removal of unwanted deposits near the bevel edge of substrates to improve process yield. The embodiments provide apparatus and methods with center and edge gas feeds as additional process knobs for selecting a most suitable bevel edge etching processes to push the edge exclusion zone further outward towards the edge of substrates. Further the embodiments provide apparatus and methods with tuning gas(es) to change the etching profile at the bevel edge and using a combination of center and edge gas feeds to flow process and tuning gases into the chamber. Both the usage of tuning gas and location of gas feed(s) affect the etching characteristics at bevel edge. Total gas flow, gap distance between the gas delivery plate and substrate surface, pressure, and types of process gas(es) are also found to affect bevel edge etching profiles. | 07-30-2009 |
| 20090272402 | METHOD AND APPARATUS FOR DETECTING PLASMA UNCONFINEMENT - A method for detecting plasma unconfinement in a reaction chamber during a bevel edge cleaning operation is provided. The method initiates with selecting a wavelength associated with expected by products of a bevel edge clean process. The method includes cleaning the bevel edge area of a substrate and monitoring the intensity of the selected wavelengths during the cleaning for deviation from a threshold wavelength intensity. The cleaning is terminated if the deviation from the threshold wavelength intensity exceeds a target deviation. | 11-05-2009 |
| 20090279989 | DYNAMIC ALIGNMENT OF WAFERS USING COMPENSATION VALUES OBTAINED THROUGH A SERIES OF WAFER MOVEMENTS - Methods and systems to optimize wafer placement repeatability in semiconductor manufacturing equipment using a controlled series of wafer movements are provided. In one embodiment, a preliminary station calibration is performed to teach a robot position for each station interfaced to facets of a vacuum transfer module used in semiconductor manufacturing. The method also calibrates the system to obtain compensation parameters that take into account the station where the wafer is to be placed, position of sensors in each facet, and offsets derived from performing extend and retract operations of a robot arm. In another embodiment where the robot includes two arms, the method calibrates the system to compensate for differences derived from using one arm or the other. During manufacturing, the wafers are placed in the different stations using the compensation parameters. | 11-12-2009 |
| 20100024186 | SERVICING A PLASMA PROCESSING SYSTEM WITH A ROBOT - A method for servicing a plasma processing system. The plasma processing system may include a plasma chamber. The plasma chamber may include a top piece and a bottom piece, wherein the top piece may be disposed above the bottom piece. The method may include using a robot device to control a lift mechanism to lift the top piece from the bottom piece. The method may also include extending a first member of the robot device into the top piece to perform a first set of tasks according to a first set of service procedures. The method may also include extending a second member of the robot device into the bottom piece to perform a second set of tasks according to a second set of service procedures. | 02-04-2010 |
| 20100096087 | Apparatus For Aligning Electrodes In A Process Chamber to Protect An Exclusion Area Within An Edge Environ Of A Wafer - Positional relationships are established in a process chamber. A base is configured with a lower electrode surface to support a wafer, and an upper electrode has a lower surface. A drive mounted on the base has a linkage connected to the upper electrode. A fixture placed on the lower surface moves into a desired orientation of the lower electrode. With the upper electrode loosely connected by the linkage to the drive, the fixture transfers the desired orientation to the upper electrode. The linkage is tightened to maintain the desired orientation, the fixture is removed and a process exclusion insert is mounted to the upper electrode. The drive moves the upper electrode and the insert to define an inactive process zone between the upper electrode and the wafer on the lower electrode to protect a central area of the wafer during etching of a wafer edge environ around the central area. | 04-22-2010 |
| 20100099265 | METHODS FOR REMOVING AN EDGE POLYMER FROM A SUBSTRATE - A method for generating plasma for removing an edge polymer from a substrate is provided. The method includes providing a powered electrode assembly, which includes a powered electrode, a dielectric layer, and a wire mesh disposed between the powered electrode and the dielectric layer. The method also includes providing a grounded electrode assembly disposed opposite the powered electrode assembly to form a cavity wherein the plasma is generated. The wire mesh is shielded from the plasma by the dielectric layer when the plasma is present in the cavity, which has an outlet at one end for providing the plasma to remove the edge polymer. The method further includes introducing at least one inert gas and at least one process gas into the cavity. The method yet also includes applying an RF field to the cavity using the powered electrode to generate the plasma from the inert gas and process gas. | 04-22-2010 |
| 20100100221 | Expert knowledge methods and systems for data analysis - A method for adjusting a data set defining a set of process runs, each process run having a set of data corresponding to a set of variables for a wafer processing operation is provided. A model derived from a data set is received. A new data set corresponding to one process run is received. The new data set is projected to the model. An outlier data point produced as a result of the projecting is identified. A variable corresponding to the one outlier data point is identified, the identified variable exhibiting a high contribution. A value for the variable from the new data set is identified. Whether the value for the variable is unimportant is determined. A normalized matrix of data is created, using random data and the variable that was determined to be unimportant from each of the new data set and the data set. The data set is updated with the normalized matrix of data. | 04-22-2010 |
| 20100108491 | METHODS FOR REMOVING A METAL OXIDE FROM A SUBSTRATE - A method for generating plasma for removing metal oxide from a substrate is provided. The method includes providing a powered electrode assembly, which includes a powered electrode, a dielectric layer, and a wire mesh disposed between the powered electrode and the dielectric layer. The method also includes providing a grounded electrode assembly disposed opposite the powered electrode assembly to form a cavity wherein the plasma is generated. The wire mesh is shielded from the plasma by the dielectric layer when the plasma is present in the cavity, which has an outlet at one end for providing the plasma to remove the metal oxide. The method further includes introducing at least one inert gas and at least one process gas into the cavity. The method yet also includes applying an rf field to the cavity using the powered electrode to generate the plasma from the inert and the process gas. | 05-06-2010 |
| 20100181025 | APPARATUS FOR THE REMOVAL OF A FLUORINATED POLYMER FROM A SUBSTRATE - An apparatus generating a plasma for removing fluorinated polymer from a substrate is provided. The apparatus includes a powered electrode assembly, which includes a powered electrode, a first dielectric layer, and a first wire mesh disposed between the powered electrode and the first dielectric layer. The apparatus also includes a grounded electrode assembly disposed opposite the powered electrode assembly so as to form a cavity wherein the plasma is generated. The first wire mesh is shielded from the plasma by the first dielectric layer when the plasma is present in the cavity, which has an outlet at one end for providing the plasma to remove the fluorinated polymer. | 07-22-2010 |
| 20100213173 | BEVEL PLASMA TREATMENT TO ENHANCE WET EDGE CLEAN - The various embodiments described in the specification provide improved mechanisms of removal of unwanted deposits on the bevel edge to improve process yield. The embodiments provide apparatus and methods of treating the bevel edge of a copper plated substrate to convert the copper at the bevel edge to a copper compound that can be wet etched with a fluid at a high etch selectivity in comparison to copper. In one embodiment, the wet etch of the copper compound at high selectivity to copper allows the removal of the non-volatile copper at substrate bevel edge in a wet etch processing chamber. The plasma treatment at bevel edge allows the copper at bevel edge to be removed at precise spatial control to about 2 mm or below, such as about 1 mm, about 0.5 mm or about 0.25 mm, to the very edge of substrate. In addition, the apparatus and methods described above for bevel edge copper removal do not have the problems of copper etching fluid being splashed on the device regions to cause defects and thinning of copper films. Therefore, device yield can be greatly improved. | 08-26-2010 |
| 20100253224 | MODULATED MULTI-FREQUENCY PROCESSING METHOD - A method is provided for operating a processing system having a space therein arranged to receive a gas and an electromagnetic field generating portion operable to generate an electromagnetic field within the space. The method includes providing a gas into the space, and operating the electromagnetic field generating portion with a driving potential to generate an electromagnetic field within the space to transform at least a portion of the gas into plasma. The driving potential as a function of time is based on a first potential function portion and a second potential function portion. The first potential function portion comprises a first continuous periodic portion having a first amplitude and a first frequency. The second potential function portion comprises a second periodic portion having an maximum amplitude portion, and minimum amplitude portion and a duty cycle. The maximum amplitude portion is a higher amplitude than the minimum amplitude portion. The duty cycle is the ratio of a duration of the maximum amplitude portion to the sum of the duration of the maximum amplitude portion and the duration of the minimum amplitude portion. The second periodic portion additionally has a second frequency during the maximum amplitude portion. An amplitude modulation of the second periodic portion is phase locked to the first continuous periodic portion. | 10-07-2010 |
| 20100261352 | METHOD FOR LOW-K DIELECTRIC ETCH WITH REDUCED DAMAGE - A method for etching features in a low-k dielectric layer disposed below an organic mask is provided by an embodiment of the invention. Features are etched into the low-k dielectric layer through the organic mask. A fluorocarbon layer is deposited on the low-k dielectric layer. The fluorocarbon layer is cured. The organic mask is stripped. | 10-14-2010 |
| 20100285671 | STRIP WITH REDUCED LOW-K DIELECTRIC DAMAGE - A method for forming etched features in a low-k dielectric layer disposed below the photoresist mask in a plasma processing chamber is provided. Features are etched into the low-k dielectric layer through the photoresist mask. The photoresist mask is stripped, wherein the stripping comprising at least one cycle, wherein each cycle comprises a fluorocarbon stripping phase, comprising flowing a fluorocarbon stripping gas into the plasma processing chamber, forming a plasma from the fluorocarbon stripping gas, and stopping the flow of the fluorocarbon stripping gas into the plasma processing chamber and a reduced fluorocarbon stripping phase, comprising flowing a reduced fluorocarbon stripping gas that has a lower fluorocarbon flow rate than the fluorocarbon stripping gas into the plasma processing chamber, forming the plasma from the reduced fluorocarbon stripping gas, and stopping the flow of the reduced fluorocarbon stripping gas. | 11-11-2010 |
| 20110097904 | METHOD FOR REPAIRING LOW-K DIELECTRIC DAMAGE - A method for repairing damage to a silicon based low-k dielectric layer with organic compounds, where damage replaces a methyl attached to silicon with a hydroxyl attached to silicon is provided. A repair gas comprising CH | 04-28-2011 |
| 20110108524 | LOCAL PLASMA CONFINEMENT AND PRESSURE CONTROL ARRANGEMENT AND METHODS THEREOF - An arrangement for performing pressure control within a processing chamber substrate processing is provided. The arrangement includes a peripheral ring configured at least for surrounding a confined chamber volume that is configured for sustaining a plasma for etching the substrate during substrate processing. The peripheral ring includes a plurality of slots that is configured at least for exhausting processed byproduct gas from the confined chamber volume during substrate processing. The arrangement also includes a conductive control ring that is positioned next to the peripheral ring and is configured to include plurality of slots. The pressure control is achieved by moving the conductive control ring relative to the peripheral ring such that a first slot on the peripheral ring and a second slot on the conductive control ring are offset with respect to one another in a range of zero offset to full offset. | 05-12-2011 |
| 20110165779 | METHOD OF ORIENTING AN UPPER ELECTRODE RELATIVE TO A LOWER ELECTRODE FOR BEVEL EDGE PROCESSING - Methods for orienting an upper electrode relative to a lower electrode are provided. The lower electrode is configured to have a desired existing orientation in a process chamber to define active and inactive process zones in the process chamber for processing a wafer. The method includes configuring each electrode with a reference surface, where a lower electrode reference surface is in the desired existing orientation and an upper electrode reference surface to be oriented parallel to the lower electrode reference surface. Then, temporarily holding the upper electrode reference surface oriented parallel to the lower electrode reference surface, and securing the upper electrode to a drive to mount the upper electrode reference surface parallel to the lower electrode reference surface. Other method configurations are also disclosed and illustrated. | 07-07-2011 |
