Abstract: Embodiments of the present invention include methods and apparatus for plasma processing in a process chamber using an RF power supply coupled to the process chamber via a matching network. In some embodiments, the method includes providing RF power to the process chamber by the RF power supply at a first frequency while the matching network is in a hold mode, adjusting the first frequency, using the RF power supply, to a second frequency during a first time period to ignite the plasma, adjusting the second frequency, using the RF power supply, to a known third frequency during a second time period while maintaining the plasma, and changing an operational mode of the matching network to an automatic tuning mode to reduce a reflected power of the RF power provided by the RF power supply.

Abstract: In some embodiments, a method of controlling a photoresist trimming process in a semiconductor manufacturing process may include forming a photoresist layer atop a first surface of a substrate, wherein the photoresist layer comprises a lower layer having a first pattern to be etched into the first surface of the substrate, and an upper layer having a second pattern that is not etched into the first surface of the substrate; trimming the photoresist layer in a direction parallel to the first surface of the substrate; measuring a trim rate of the second pattern using an optical measuring tool during the trimming process; and correlating the trim rate of the second pattern to a trim rate of the first pattern to control the trim rate of the first pattern during the trimming process.

Abstract: Methods and apparatus for plasma-enhanced substrate processing are provided herein. In some embodiments, a method is provided for processing a substrate in a process chamber having a plurality of electromagnets disposed about the process chamber to form a magnetic field within the process chamber at least at a substrate level. In some embodiments, the method includes determining a first direction of an external magnetic field present within the process chamber while providing no current to the plurality of electromagnets; providing a range of currents to the plurality of electromagnets to create a magnetic field within the process chamber having a second direction opposing the first direction; determining a desired magnitude in the second direction of the magnetic field over the range of currents; and processing a substrate in the process chamber using a plasma while statically providing the magnetic field at the desired magnitude.

Abstract: Embodiments of the present invention generally relate to an apparatus for processing substrates having improved magnetic shielding. One embodiment of the present invention provides a plasma processing chamber having an RF match, a plasma source and a plasma region defined between a chamber ceiling and a substrate support. At least one of the RF match, plasma source and plasma region is shielded from any external magnetic field with a shielding material that has a relative magnetic permeability ranging from about 20,000 to about 200,000. As a result, the inherent process non-uniformities of the hardware may be reduced effectively without the overlaid non-uniformities from external factors such as earth's geomagnetic field.

Abstract: Embodiments of the present invention generally provide an apparatus with a recess and a cavity formed therein for future hardware retrofit and uniformity enhancement and methods for controlling the same. In one embodiment, a substrate support includes a supporting body having an outer wall, a ground path disposed against and bounding the outer wall of the supporting body, a mounting plate coupled to a lower surface of the supporting body, wherein the mounting plate includes a lip extending outward from the mounting plate defining an upper surface; and a recess formed at a perimeter of the supporting body above the upper surface of the lip of the mounting plate, the recess lining on the ground path extending at least partially to the mounting plate.

Abstract: Embodiments of the present invention relate to an apparatus for providing processing gases to a process chamber with improved uniformity. One embodiment of the present invention provides a gas delivery assembly. The gas delivery assembly includes a hub, a nozzle, and one or more gas diffusers disposed in the nozzle. The nozzle has a cylindrical body with a side wall and a top surface. A plurality of injection passages are formed inside the nozzle to deliver processing gases into the process chamber via a plurality of outlets disposed in the side wall. The injection passages are configured to direct process gases out of each outlet disposed in the side wall in a direction which is not radially aligned with a centerline of the hub.

Abstract: Embodiments of the present disclosure generally provide apparatus and method for cooling a substrate support in a uniform manner. One embodiment of the present disclosure provides a cooling assembly for a substrate support. The cooling assembly includes a cooling base having a first side for contacting the substrate support and providing cooling to the substrate support, a diffuser disposed on a second side of the cooling base, wherein the diffuser defines a plurality of cooling paths for delivering a cooling fluid towards the cooling base in a parallel manner, and an inlet/outlet plate disposed under the diffuser, wherein the inlet/outlet plate is provides an interface between the diffuser and an inlet and outlet of a cooling fluid.

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; one or more inductive coils disposed above the dielectric lid to inductively couple RF energy into the processing volume above the substrate support; and one or more first electromagnets to form a first static magnetic field that is substantially vertical in direction and axisymmetric about a central processing axis of the process chamber, and having a magnitude of about 2 to about 10 gauss within the processing volume proximate the lid.

Abstract: Embodiments of impedance matching networks are provided herein. In some embodiments, an impedance matching network may include a coaxial resonator having an inner and an outer conductor. A tuning capacitor may be provided for variably controlling a resonance frequency of the coaxial resonator. The tuning capacitor may be formed by a first tuning electrode and a second tuning electrode and an intervening dielectric, wherein the first tuning electrode is formed by a portion of the inner conductor. A load capacitor may be provided for variably coupling energy from the inner conductor to a load. The load capacitor may be formed by the inner conductor, an adjustable load electrode, and an intervening dielectric.

Abstract: Electrostatic chucks (ESCs) with RF and temperature uniformity are described. For example, an ESC includes a top dielectric layer. An upper metal portion is disposed below the top dielectric layer. A second dielectric layer is disposed above a plurality of pixilated resistive heaters and surrounded in part by the upper metal portion. A third dielectric layer is disposed below the second dielectric layer, with a boundary between the third dielectric layer and the second dielectric layer. A plurality of vias is disposed in the third dielectric layer. A bus power bar distribution layer is disposed below and coupled to the plurality of vias. A fourth dielectric layer is disposed below the bus bar power distribution layer, with a boundary between the fourth dielectric layer and the third dielectric layer. A metal base is disposed below the fourth dielectric layer. The metal base includes a plurality of high power heater elements housed therein.

Abstract: Methods for calibrating RF power applied to a plurality of RF coils are provided. In some embodiments, a method of calibrating RF power applied to a first and second RF coil of a process chamber having a power divider to control a first ratio equal to a first magnitude of RF power provided to the first RF coil divided by a second magnitude of RF power provided to the second RF coil, may include measuring a plurality of first ratios over a range of setpoint values of the power divider, comparing the plurality of measured first ratios to a plurality of reference first ratios, and adjusting an actual value of the power divider at a given setpoint value such that the first ratio of the power divider at the given setpoint matches the corresponding reference first ratio to within a first tolerance level.

Abstract: Methods for etching a substrate are provided herein. In some embodiments, a method of etching a substrate may include generating a plasma by providing only a first RF signal having a first frequency and a first duty cycle; applying only a second RF signal to bias the plasma towards the substrate, wherein the second RF signal has the first frequency and a second duty cycle different than the first duty cycle; adjusting a phase variance between the first and second RF signals to control an ion energy distribution in the plasma; and etching the substrate with the plasma.

Abstract: Embodiments of the present invention generally provide an inductively coupled plasma (ICP) reactor having a substrate RF bias that is capable of control of the RF phase difference between the ICP source (a first RF source) and the substrate bias (a second RF source) for plasma processing reactors used in the semiconductor industry. Control of the RF phase difference provides a powerful knob for fine process tuning. For example, control of the RF phase difference may be used to control one or more of average etch rate, etch rate uniformity, etch rate skew, critical dimension (CD) uniformity, and CD skew, CD range, self DC bias control, and chamber matching.

Abstract: In a plasma reactor having an RF plasma source power applicator at its ceiling, an integrally formed grid liner includes a radially extending plasma confinement ring and an axially extending side wall liner. The plasma confinement ring extends radially outwardly near the plane of a workpiece support surface from a pedestal side wall, and includes an annular array of radial slots, each of the slots having a narrow width corresponding to an ion collision mean free path length of a plasma in the chamber. The side wall liner covers an interior surface of the chamber side wall and extends axially from a height near a height of said workpiece support surface to the chamber ceiling.

Abstract: Embodiments of field enhanced inductively coupled plasma reactors and methods of use of same are provided herein. In some embodiments, a field enhanced inductively coupled plasma processing system may include a process chamber having a dielectric lid and a plasma source assembly disposed above the dielectric lid. The plasma source assembly includes one or more coils configured to inductively couple RF energy into the process chamber to form and maintain a plasma therein, one or more electrodes configured to capacitively couple RF energy into the process chamber to form the plasma therein, wherein the one or more electrodes are electrically coupled to one of the one or more coils, and an RF generator coupled to the one or more inductive coils and the one or more electrodes. In some embodiments, a heater element may be disposed between the dielectric lid and the plasma source assembly.

Abstract: Methods for calibrating RF power applied to a plurality of RF coils are provided. In some embodiments, a method of calibrating RF power applied to a first and second RF coil of a process chamber having a power divider to control a first ratio equal to a first magnitude of RF power provided to the first RF coil divided by a second magnitude of RF power provided to the second RF coil, may include measuring a plurality of first ratios over a range of setpoint values of the power divider, comparing the plurality of measured first ratios to a plurality of reference first ratios, and adjusting an actual value of the power divider at a given setpoint value such that the first ratio of the power divider at the given setpoint matches the corresponding reference first ratio to within a first tolerance level.

Abstract: Apparatus for plasma processing are provided. In some embodiments, an RF feed structure includes a first RF feed to couple RF power to a plurality of symmetrically arranged stacked first RF coil elements; a second RF feed coaxially disposed about the first RF feed and electrically insulated therefrom, the second RF feed to couple RF power to a plurality of symmetrically arranged stacked second RF coil elements coaxially disposed with respect to the first RF coil elements. In some embodiments, a plasma processing apparatus includes a first RF coil; a second RF coil coaxially disposed with respect to the first RF coil; a first RF feed coupled to the first RF coil to provide RF power thereto; and a second RF feed coaxially disposed with respect to the first RF feed and electrically insulated therefrom, the second RF feed coupled to the second RF coil to provide RF power thereto.

Abstract: Embodiments of dual mode inductively coupled plasma reactors and methods of use of same are provided herein. In some embodiments, a dual mode inductively coupled plasma processing system may include a process chamber having a dielectric lid and a plasma source assembly disposed above the dielectric lid. The plasma source assembly includes a plurality of coils configured to inductively couple RF energy into the process chamber to form and maintain a plasma therein, a phase controller for adjusting the relative phase of the RF current applied to each coil in the plurality of coils, and an RF generator coupled to the phase controller and the plurality of coils.

Abstract: Methods and apparatus for plasma processing are provided herein. In some embodiments, a plasma processing apparatus includes a process chamber having an interior processing volume; a first RF coil disposed proximate the process chamber to couple RF energy into the processing volume; and a second RF coil disposed proximate the process chamber to couple RF energy into the processing volume, the second RF coil disposed coaxially with respect to the first RF coil, wherein the first and second RF coils are configured such that RF current flowing through the first RF coil is out of phase with RF current flowing through the RF second coil.

Abstract: Embodiments of impedance matching networks are provided herein. In some embodiments, an impedance matching network may include a coaxial resonator having an inner and an outer conductor. A tuning capacitor may be provided for variably controlling a resonance frequency of the coaxial resonator. The tuning capacitor may be formed by a first tuning electrode and a second tuning electrode and an intervening dielectric, wherein the first tuning electrode is formed by a portion of the inner conductor. A load capacitor may be provided for variably coupling energy from the inner conductor to a load. The load capacitor may be formed by the inner conductor, an adjustable load electrode, and an intervening dielectric.