Abstract: Embodiments of improved apparatus for maintaining low non-uniformity over the life of a target are provided herein. In some embodiments, an apparatus includes a substrate support within a volume of a chamber body, opposite a target assembly of a lid atop the chamber body, with a surface; a shield disposed within the chamber body comprising one or more sidewalls surrounding the volume, the shield extending downward to below a top surface of the substrate support, radially inward, and returning upward forming an extending lip; and a first ring having (i) a first portion comprising an opening having a ceramic isolator, disposed therein, resting on top of the extending lip, and (ii) a second portion extending away from the first portion toward the surface, wherein the substrate support, over a life of the target, is configured to raise and lower, relative to the first ring, a substrate disposed on the surface.

Abstract: In some implementations described herein, a collimator that is biasable is provided. The ability to bias the collimator allows control of the electric field through which the sputter species pass. In some implementations of the present disclosure, a collimator that has a high effective aspect ratio while maintaining a low aspect ratio along the periphery of the collimator of the hexagonal array of the collimator is provided. In some implementations, a collimator with a steep entry edge in the hexagonal array is provided. It has been found that use of a steep entry edge in the collimator reduces deposition overhang and clogging of the cells of the hexagonal array. These various features lead to improve film uniformity and extend the life of the collimator and process kit.

Abstract: Embodiments of improved methods and apparatus for maintaining low non-uniformity over the course of the life of a target are provided herein. In some embodiments, a method of processing a substrate in a physical vapor deposition chamber includes: disposing a substrate atop a substrate support having a cover ring that surrounds the substrate support such that an upper surface of the substrate is positioned at a first distance above an upper surface of the cover ring; sputtering a source material from a target disposed opposite the substrate support to deposit a film atop the substrate while maintaining the first distance; and lowering the substrate support with respect to the cover ring and sputtering the source material from the target to deposit films atop subsequent substrates over a life of the target.

Abstract: Embodiments of method for igniting a plasma are provided herein. In some embodiments, a method for igniting a plasma includes: flowing a process gas into a process chamber to increase a pressure within the process chamber to a first pressure; applying a first bias voltage from a collimator power source to a collimator disposed within the process chamber; and applying a second power to a sputtering source disposed in the process chamber above the collimator after the first pressure has been reached and the first bias voltage is applied to ignite the plasma.

Abstract: In some implementations described herein, a collimator that is biasable is provided. The ability to bias the collimator allows control of the electric field through which the sputter species pass. In some implementations of the present disclosure, a collimator that has a high effective aspect ratio while maintaining a low aspect ratio along the periphery of the collimator of the hexagonal array of the collimator is provided. In some implementations, a collimator with a steep entry edge in the hexagonal array is provided. It has been found that use of a steep entry edge in the collimator reduces deposition overhang and clogging of the cells of the hexagonal array. These various features lead to improve film uniformity and extend the life of the collimator and process kit.

Abstract: Methods and apparatus for a magnetron assembly are provided herein. In some embodiments, a magnetron assembly includes a shunt plate having a central axis and rotatable about the central axis, a closed loop magnetic pole coupled to a first surface of the shunt plate and disposed 360 degrees along a peripheral edge of the shunt plate, and an open loop magnetic pole coupled at a the first surface of the shunt plate wherein the open loop magnetic pole comprises two rows of magnets disposed about the central axis.

Abstract: In some implementations described herein, a collimator that is biasable is provided. The ability to bias the collimator allows control of the electric field through which the sputter species pass. In some implementations of the present disclosure a collimator that has a high effective aspect ratio while maintaining a low aspect ratio along the periphery of the collimator of the hexagonal array of the collimator is provided. In some implementations, a collimator with a steep entry edge in the hexagonal array is provided. It has been found that use of a steep entry edge in the collimator reduces deposition overhang and clogging of the cells of the hexagonal array. These various features lead to improve film uniformity and extend the life of the collimator and process kit.

Abstract: Methods and apparatus to minimize electromagnetic interference between adjacent process chambers of a cluster tool are described. The start time of the subject recipe is controlled based on the electromagnetic process window of the subject process chamber, the electromagnetic window of the first adjacent process chamber and of an optional second adjacent process chamber. The start time of the subject process chamber is controlled to prevent temporal overlap of the electromagnetic window of the subject chamber with the electromagnetic window of an adjacent chamber.

Abstract: A magnetic field forming apparatus includes a support member having a first side and a second side coupling a first end to a second end and an axis of rotation between the first end and the second end; a first body coupled to the first end of the support member and extending away from the first side of the support member, wherein the first body has a plurality of first magnets coupled to a bottom of the first body; a second body rotatably coupled to the second end of the support member and extending away from the second side of the support member, wherein the second body has a plurality of second magnets coupled to a bottom of the second body, wherein the plurality of the first magnets are disposed about 180 degrees from the plurality of second magnets with respect to the axis of rotation of the support member.

Abstract: Methods and apparatus for controlling the ion fraction in physical vapor deposition processes are disclosed. In some embodiments, a process chamber for processing a substrate having a given diameter includes: an interior volume and a target to be sputtered, the interior volume including a central portion and a peripheral portion; a rotatable magnetron above the target to form an annular plasma in the peripheral portion; a substrate support disposed in the interior volume to support a substrate having the given diameter; a first set of magnets disposed about the body to form substantially vertical magnetic field lines in the peripheral portion; a second set of magnets disposed about the body and above the substrate support to form magnetic field lines directed toward a center of the support surface; a first power source to electrically bias the target; and a second power source to electrically bias the substrate support.

Abstract: Embodiments of method for igniting a plasma are provided herein. In some embodiments, a method for igniting a plasma includes: flowing a process gas into a process chamber to increase a pressure within the process chamber to a first pressure; applying a first bias voltage from a collimator power source to a collimator disposed within the process chamber; and applying a second power to a sputtering source disposed in the process chamber above the collimator after the first pressure has been reached and the first bias voltage is applied to ignite the plasma.

Abstract: In some implementations described herein, a collimator that is biasable is provided. The ability to bias the collimator allows control of the electric field through which the sputter species pass. In some implementations of the present disclosure a collimator that has a high effective aspect ratio while maintaining a low aspect ratio along the periphery of the collimator of the hexagonal array of the collimator is provided. In some implementations, a collimator with a steep entry edge in the hexagonal array is provided. It has been found that use of a steep entry edge in the collimator reduces deposition overhang and clogging of the cells of the hexagonal array. These various features lead to improve film uniformity and extend the life of the collimator and process kit.

Abstract: Embodiments of improved methods and apparatus for maintaining low non-uniformity over the course of the life of a target are provided herein. In some embodiments, a method of processing a substrate in a physical vapor deposition chamber includes: disposing a substrate atop a substrate support having a cover ring that surrounds the substrate support such that an upper surface of the substrate is positioned at a first distance above an upper surface of the cover ring; sputtering a source material from a target disposed opposite the substrate support to deposit a film atop the substrate while maintaining the first distance; and lowering the substrate support with respect to the cover ring and sputtering the source material from the target to deposit films atop subsequent substrates over a life of the target.

Abstract: Methods and apparatus for a magnetron assembly are provided herein. In some embodiments, a magnetron assembly includes a shunt plate having a central axis and rotatable about the central axis, a closed loop magnetic pole coupled to a first surface of the shunt plate and disposed 360 degrees along a peripheral edge of the shunt plate, and an open loop magnetic pole coupled at a the first surface of the shunt plate wherein the open loop magnetic pole comprises two rows of magnets disposed about the central axis.

Abstract: A magnetic field forming apparatus includes a support member having a first side and a second side coupling a first end to a second end and an axis of rotation between the first end and the second end; a first body coupled to the first end of the support member and extending away from the first side of the support member, wherein the first body has a plurality of first magnets coupled to a bottom of the first body; a second body rotatably coupled to the second end of the support member and extending away from the second side of the support member, wherein the second body has a plurality of second magnets coupled to a bottom of the second body, wherein the plurality of the first magnets are disposed about 180 degrees from the plurality of second magnets with respect to the axis of rotation of the support member.