Abstract: Embodiments of the disclosure provide an integrated system for performing a measurement process and a lithographic overlay error correction process on a semiconductor substrate in a single processing system. In one embodiment, a processing system includes at least a load lock chamber, a transfer chamber coupled to the load lock chamber, an ion implantation processing chamber coupled to or in the transfer chamber, and a metrology tool coupled to the transfer chamber, wherein the metrology tool is adapted to obtain stress profile or an overlay error on a substrate disposed in the metrology tool.

Abstract: Implementations of the present disclosure generally relate to the fabrication of integrated circuits. More particularly, the implementations described herein provide techniques for deposition of boron-containing amorphous carbon films on a substrate with reduced particle contamination. In one implementation, the method comprises flowing a hydrocarbon-containing gas mixture into a processing volume having a substrate positioned therein, flowing a boron-containing gas mixture into the processing volume, stabilizing the pressure in the processing volume for a predefined RF-on delay time period, generating an RF plasma in the processing volume after the predefined RF-on delay time period expires to deposit a boron-containing amorphous film on the substrate, exposing the processing volume of the process chamber to a dry cleaning process and depositing an amorphous boron season layer over at least one surface in the processing volume of the process chamber.

Abstract: Implementations of the present disclosure generally relate to methods and apparatus for generating and controlling plasma, for example RF filters, used with plasma chambers. In one implementation, a plasma processing apparatus is provided. The plasma processing apparatus comprises a chamber body, a powered gas distribution manifold enclosing a processing volume and a radio frequency (RF) filter. A pedestal having a substrate-supporting surface is disposed in the processing volume. A heating assembly comprising one or more heating elements is disposed within the pedestal for controlling a temperature profile of the substrate-supporting surface. A tuning assembly comprising a tuning electrode is disposed within the pedestal between the one or more heating elements and the substrate-supporting surface. The RF filter comprises an air core inductor, wherein at least one of the heating elements, the tuning electrode, and the gas distribution manifold is electrically coupled to the RF filter.

Abstract: Embodiments described herein relate to methods for determining a cleaning endpoint. A first plasma cleaning process may be performed in a clean chamber environment to determine a clean time function defined by a first slope. A second plasma cleaning process may be performed in an unclean chamber environment to determine a clean time function defined by a second slope. The first and second slope may be compared to determine a clean endpoint time.

Abstract: Implementations of the present disclosure generally relate to the fabrication of integrated circuits. More particularly, the implementations described herein provide techniques for deposition of boron-containing amorphous carbon films on a substrate with reduced particle contamination. In one implementation, the method comprises flowing a hydrocarbon-containing gas mixture into a processing volume having a substrate positioned therein, flowing a boron-containing gas mixture into the processing volume, stabilizing the pressure in the processing volume for a predefined RF-on delay time period, generating an RF plasma in the processing volume after the predefined RF-on delay time period expires to deposit a boron-containing amorphous film on the substrate, exposing the processing volume of the process chamber to a dry cleaning process and depositing an amorphous boron season layer over at least one surface in the processing volume of the process chamber.

Abstract: The present disclosure generally relates to processing chamber seasoning layers having a graded composition. In one example, the seasoning layer is a boron-carbon-nitride (BCN) film. The BCN film may have a greater composition of boron at the base of the film. As the BCN film is deposited, the boron concentration may approach zero, while the relative carbon and nitrogen concentration increases. The BCN film may be deposited by initially co-flowing a boron precursor, a carbon precursor, and a nitrogen precursor. After a first period of time, the flow rate of the boron precursor may be reduced. As the flow rate of boron precursor is reduced, RF power may be applied to generate a plasma during deposition of the seasoning layer.

Abstract: Embodiments described herein relate to methods for determining a cleaning endpoint. A first plasma cleaning process may be performed in a clean chamber environment to determine a clean time function defined by a first slope. A second plasma cleaning process may be performed in an unclean chamber environment to determine a clean time function defined by a second slope. The first and second slope may be compared to determine a clean endpoint time.

Abstract: A plasma source is provided including a core element extending from a first end to a second end along a first axis. The plasma source further includes one or more coils disposed around respective one or more first portions of the core element. The plasma source further includes a plasma block having one or more interior walls at least partially enclosing an annular plasma-generating volume that is disposed around a second portion of the core element. The annular plasma-generating volume includes a first region that is symmetrical about a plurality of perpendicular axes that are perpendicular to a first point positioned on the first axis, the first region having a width in a direction parallel to the first axis and a depth in a direction perpendicular from the first axis. The first region has a width that is at least three times greater than the depth of the first region.

Abstract: A plasma source is provided including a core element extending from a first end to a second end along a first axis. The plasma source further includes one or more coils disposed around respective one or more first portions of the core element. The plasma source further includes a plasma block having one or more interior walls at least partially enclosing an annular plasma-generating volume that is disposed around a second portion of the core element. The annular plasma-generating volume includes a first region that is symmetrical about a plurality of perpendicular axes that are perpendicular to a first point positioned on the first axis, the first region having a width in a direction parallel to the first axis and a depth in a direction perpendicular from the first axis. The first region has a width that is at least three times greater than the depth of the first region.

Abstract: A remote plasma source is disclosed that includes a core element and a first plasma block including one or more surfaces at least partially enclosing an annular-shaped plasma generating region that is disposed around a first portion of the core element. The remote plasma source further comprises one or more coils disposed around respective second portions of the core element. The remote plasma source further includes an RF power source configured to drive a RF power signal onto the one or more coils that is based on a determined impedance of the plasma generating region. Energy from the RF power signal is coupled with the plasma generating region via the one or more coils and the core element.

Abstract: Embodiments of the present disclosure generally relate to methods for conditioning an interior wall surface of a remote plasma generator. In one embodiment, a method for processing a substrate is provided. The method includes exposing an interior wall surface of a remote plasma source to a conditioning gas that is in excited state to passivate the interior wall surface of the remote plasma source, wherein the remote plasma source is coupled through a conduit to a processing chamber in which a substrate is disposed, and the conditioning gas comprises an oxygen-containing gas, a nitrogen-containing gas, or a combination thereof. The method has been observed to be able to improve dissociation/recombination rate and plasma coupling efficiency in the processing chamber, and therefore provides repeatable and stable plasma source performance from wafer to wafer.

Abstract: Implementations described herein protect a substrate support from corrosive cleaning gases used at high temperatures. In one embodiment, a substrate support has a shaft and a heater. The heater has a body. The body has a top surface, a side surface and a bottom surface. The top surface is configured to support a substrate during plasma processing of the substrate. A covering is provided for at least two of the top surface, side surface and bottom surface. The covering is selected to resist corrosion of the body at temperatures in excess of about 400 degrees Celsius.