Abstract: Target assemblies and PVD chambers including target assemblies are disclosed. The target assembly includes a target that has a concave shaped target. When used in a PVD chamber, the concave target provides more radially uniform deposition on a substrate disposed in the sputtering chamber.

Abstract: Embodiments of a sputter source for semiconductor process chambers are provided herein. In some embodiments, a sputter source for a semiconductor process chamber may include: a target comprising a magnetic material to be deposited on a substrate, the magnetic material including a front surface where material is to be sputtered and an opposing back surface; and an outer magnet disposed proximate a back surface of the target and arranged symmetrically with respect to a central axis of the target, wherein the target has an annular groove formed in the back surface of the target disposed proximate the outer magnet to reduce a magnetic permeability of a region of the target proximate the outer magnet, wherein the groove is an unfilled v-shaped groove having an inner angle greater than 90 degrees.

Abstract: Methods and apparatus for controlling a magnetic field in a plasma chamber are provided herein. In some embodiments, a process chamber liner may include a cylindrical body, an inner electromagnetic cosine-theta (cos ?) coil ring including a first plurality of inner coils embedded in the body and configured to generate a magnetic field in a first direction, and an outer electromagnetic cosine-theta (cos ?) coil ring including a second plurality of outer coils embedded in the body and configured to generate a magnetic field in a second direction orthogonal to the first direction, wherein the outer electromagnetic cos ? coil ring is disposed concentrically about the inner electromagnetic cos ? coil ring.

Abstract: Implementations described herein provide a magnetic ring which enables both lateral and azimuthal tuning of the plasma in a processing chamber. In one embodiment, the magnetic ring has a body. The body has a top surface and a bottom surface, and a plurality of magnets are disposed on the bottom surface of the body.

Abstract: Embodiments of a sputter source for semiconductor process chambers are provided herein. In some embodiments, a sputter source for a semiconductor process chamber may include: a target comprising a magnetic material to be deposited on a substrate, the magnetic material including a front surface where material is to be sputtered and an opposing back surface; and an outer magnet disposed proximate a back surface of the target and arranged symmetrically with respect to a central axis of the target, wherein the target has an annular groove formed in the back surface of the target disposed proximate the outer magnet to reduce a magnetic permeability of a region of the target proximate the outer magnet, wherein the groove is an unfilled v-shaped groove having an inner angle greater than 90 degrees.

Abstract: Methods and apparatus for controlling a magnetic field in a plasma chamber are provided herein. In some embodiments, a process chamber liner may include a cylindrical body, an inner electromagnetic cosine-theta (cos ?) coil ring including a first plurality of inner coils embedded in the body and configured to generate a magnetic field in a first direction, and an outer electromagnetic cosine-theta (cos ?) coil ring including a second plurality of outer coils embedded in the body and configured to generate a magnetic field in a second direction orthogonal to the first direction, wherein the outer electromagnetic cos ? coil ring is disposed concentrically about the inner electromagnetic cos ? coil ring.

Abstract: Embodiments of the invention generally provide a processing chamber used to perform a physical vapor deposition (PVD) process and methods of depositing multi-compositional films. The processing chamber may include: an improved RF feed configuration to reduce any standing wave effects; an improved magnetron design to enhance RF plasma uniformity, deposited film composition and thickness uniformity; an improved substrate biasing configuration to improve process control; and an improved process kit design to improve RF field uniformity near the critical surfaces of the substrate.

Abstract: Methods for depositing a layer on a substrate are provided herein. In some embodiments, a method of depositing a metal-containing layer on a substrate in a physical vapor deposition (PVD) chamber may include applying RF power at a VHF frequency to a target comprising a metal disposed in the PVD chamber above the substrate to form a plasma from a plasma-forming gas; optionally applying DC power to the target; sputtering metal atoms from the target using the plasma while maintaining a first pressure in the PVD chamber sufficient to ionize a predominant portion of the sputtered metal atoms; and controlling the potential on the substrate to be the same polarity as the ionized metal atoms to deposit a metal-containing layer on the substrate.

Abstract: Embodiments described herein generally relate to plasma process apparatus. In one embodiment, the plasma process apparatus includes a plasma source assembly. The plasma source assembly may include a first coil, a second coil surrounding the first coil, and a magnetic device disposed outside the first and inside the second coil. The magnet enables additional tuning which improves uniformity control of the processes on the substrate.

Abstract: Implementations described herein provide a magnetic ring which enables both lateral and azimuthal tuning of the plasma in a processing chamber. In one embodiment, the magnetic ring has a body. The body has a top surface and a bottom surface, and a plurality of magnets are disposed on the bottom surface of the body.

Abstract: In some embodiments, a plasma processing apparatus includes a processing chamber to process a substrate; a mounting surface defined within the processing chamber to support a substrate disposed within the processing chamber; a showerhead disposed within the processing chamber and aligned so as to face the mounting surface, the showerhead defining a plurality of orifices to introduce a process gas into the processing chamber toward a substrate disposed within the processing chamber; and one or more magnets supported by the showerhead and arranged so that a radial component of a magnetic field applied by each of the one or more magnets has a higher flux density proximate a first region corresponding to an edge surface region of a substrate when disposed within the processing chamber than at a second region corresponding to an interior surface region of a substrate when disposed within the processing chamber.

Abstract: Methods and apparatus for controlling a magnetic field in a plasma chamber are provided herein. In some embodiments, a process chamber liner may include a cylindrical body, an inner electromagnetic cosine-theta (cos ?) coil ring including a first plurality of inner coils embedded in the body and configured to generate a magnetic field in a first direction, and an outer electromagnetic cosine-theta (cos ?) coil ring including a second plurality of outer coils embedded in the body and configured to generate a magnetic field in a second direction orthogonal to the first direction, wherein the outer electromagnetic cos ? coil ring is disposed concentrically about the inner electromagnetic cos ? coil ring.

Abstract: Embodiments of the present invention generally provide chamber cleaning methods for cleaning a plasma processing chamber with minimum likelihood of erosion occurred on the chamber components so as to extend service life of chamber components for semiconductor plasma applications. In one embodiment, a method of extending chamber component life in a processing chamber includes supplying a cleaning gas mixture into a plasma processing chamber, applying a RF source power to the plasma processing chamber, and applying a voltage to a substrate support assembly disposed in the processing chamber during cleaning.

Abstract: Electrostatic chucks with variable pixelated magnetic field are described. For example, an electrostatic chuck (ESC) includes a ceramic plate having a front surface and a back surface, the front surface for supporting a wafer or substrate. A base is coupled to the back surface of the ceramic plate. A plurality of electromagnets is disposed in the base, the plurality of electromagnets configured to provide pixelated magnetic field tuning capability for the ESC.

Abstract: Embodiments of magnetrons suitable to provide extended target life in radio frequency (RF) plasmas are provided. In some embodiments, apparatus and methods are provided to control film uniformity while extending the target life in an RF plasma. In some embodiments, the present invention may facilitate one or more of very high target utilization, more uniform metal ionization, and more uniform deposition on a substrate. In some embodiments, a magnetron may include a magnet support member having a center of rotation; and a plurality of magnetic tracks, each track comprising a pair of open loop magnetic poles parallel to and spaced apart from each other, wherein one track is disposed near the center of the magnet support member, and wherein a different track is disposed in a position corresponding to an outer edge of a target material to be deposited on a substrate when installed in the PVD process chamber.

Abstract: In a plasma-enhanced physical vapor deposition reactor, uniformity of radial distribution of the deposition rate across the workpiece is enhanced by applying both RF and D.C. power to the target and adjusting the power levels of the RF and D.C. power independently. Further optimization is obtained by adjusting the height of the magnet above the target, adjusting the radius of the orbital motion of the magnet above the target and providing an angle edge surface of the target.

Abstract: Methods and apparatus for plasma-enhanced substrate processing are provided herein. In some embodiments, an apparatus for processing a substrate includes: a process chamber having an internal processing volume disposed beneath a dielectric lid of the process chamber; a substrate support disposed in the process chamber; two or more concentric inductive coils disposed above the dielectric lid to inductively couple RF energy into the processing volume above the substrate support; and an electromagnetic dipole disposed proximate a top surface of the dielectric lid between two adjacent concentric inductive coils of the two or more concentric inductive coils.

Abstract: Embodiments of inductively coupled plasma (ICP) reactors are provided herein. In some embodiments, a dielectric window for an inductively coupled plasma reactor includes: a body including a first side, a second side opposite the first side, an edge, and a center, wherein the dielectric window has a dielectric coefficient that varies spatially. In some embodiments, an apparatus for processing a substrate includes: a process chamber having a processing volume disposed beneath a lid of the process chamber; and one or more inductive coils disposed above the lid to inductively couple RF energy into and to form a plasma in the processing volume above a substrate support disposed within the processing volume; wherein the lid is a dielectric window comprising a first side and an opposing second side that faces the processing volume, and wherein the lid has a dielectric coefficient that spatially varies to provide a varied power coupling of RF energy from the one or more inductive coils to the processing volume.

Abstract: A multi-step process performed in a plasma sputter chamber including sputter deposition from the target and argon sputter etching of the substrate. The chamber includes a quadruple electromagnetic coil array coaxially arranged in a rectangular array about a chamber axis outside the sidewalls of a plasma sputter reactor in back of an RF coil within the chamber. The coil currents can be separately controlled to produce different magnetic field distributions, for example, between a sputter deposition mode in which the sputter target is powered to sputter target material onto a wafer and a sputter etch mode in which the RF coil supports the argon sputtering plasma. A TaN/Ta barrier is first sputter deposited with high target power and wafer bias. Argon etching is performed with even higher wafer bias. A flash step is applied with reduced target power and wafer bias.

Abstract: Methods for forming interconnect structures are provided herein. In some embodiments, a method for forming an interconnect on a substrate may include depositing a material atop an upper surface of the substrate and atop one or more surfaces of a feature disposed in the substrate by a first deposition process that deposits the material at a faster rate on the upper surface than on a bottom surface of the feature; depositing the material atop the upper surface of the substrate and atop one or more surfaces of the feature by a second deposition process that deposits the material at a greater rate on the bottom surface of the feature than on the upper surface of the substrate; and heating the deposited material to draw the deposited material towards the bottom surface of the feature to at least partially fill the feature with the deposited material.