Abstract: Embodiments of the invention provide processes for vapor depositing tungsten-containing materials, such as metallic tungsten and tungsten nitride. In one embodiment, a method for forming a tungsten-containing material is provided which includes positioning a substrate within a processing chamber containing a lid plate, heating the lid plate to a temperature within a range from about 120° C. to about 180° C., exposing the substrate to a reducing gas during a pre-nucleation soak process, and depositing a first tungsten nucleation layer on the substrate during a first atomic layer deposition process within the processing chamber. The method further provides depositing a tungsten nitride layer on the first tungsten nucleation layer during a vapor deposition process, depositing a second tungsten nucleation layer on the tungsten nitride layer during a second atomic layer deposition process within the processing chamber, and exposing the substrate to another reducing gas during a post-nucleation soak process.

Abstract: Embodiments of the invention provide apparatuses for vapor depositing tungsten-containing materials, such as metallic tungsten and tungsten nitride. In one embodiment, a processing chamber is provided which includes a lid assembly containing a lid plate, a showerhead, a mixing cavity, a distribution cavity, and a resistive heating element contained within the lid plate. In one example, the resistive heating element is configured to provide the lid plate at a temperature within a range from about 120° C. to about 180° C., preferably, from about 140° C. to about 160° C., more preferably, from about 145° C. to about 155° C. The mixing cavity may be in fluid communication with a tungsten precursor source containing tungsten hexafluoride and a nitrogen precursor source containing ammonia. In some embodiments, a single processing chamber may be used to deposit metallic tungsten and tungsten nitride materials by CVD processes.

Abstract: An apparatus for cyclical depositing of thin films on semiconductor substrates, comprising a process chamber having a gas distribution system with separate paths for process gases and an exhaust system synchronized with operation of valves dosing the process gases into a reaction region of the chamber.

Abstract: A lid assembly for a semiconductor processing system is provided. The lid assembly generally includes a lid having a gas manifold mounted on a first side and a baffle plate mounted on a second side. The gas manifold is configured to deliver a plurality of gases to a plenum defined between the baffle plate and the lid. The gases are mixed within a recess formed in the baffle plate before exiting into the processing system through a singular passage.

Abstract: A showerhead assembly for distributing gases within a processing chamber is provided. In one embodiment, the showerhead assembly includes a cylindrical member having a faceplate coupled thereto. The cylindrical member has an outwardly extending first flange at a first end. The faceplate is coupled to a second end of the cylindrical member and has a plurality of holes formed though a center region of the faceplate. The joint between the cylindrical member and the faceplate allow for relative movement when subjected to thermal stresses. In another embodiment, at least one clamp member retains the faceplate to the second end of the cylindrical member.

Abstract: A set of lift pins defines a storage location for a substrate in a substrate processing chamber. Each lift pin has an actuating mechanism including a translating mechanism that translates vertical actuation into horizontal motion. The actuating mechanism may include a base, a mechanism adapted to raise and lower the base, and a lever pivotally mounted on the base. The lift pin may be fixedly mounted on the lever. A stop may be adjacent the base and adapted to engage the lever to pivot the lever as the base is lowered.

Abstract: A substrate support assembly for supporting a substrate during processing is provided. In one embodiment, a support assembly includes a ceramic body having an embedded heating element and a base plate. The base plate and the ceramic body define a channel therebetween adapted to supply purge gas to a perimeter of a substrate disposed on the support assembly. The base plate is fastened to the body by brazing, adhering, fastening, press fitting or by mating engaging portions of a retention device such as a bayonet fitting.

Abstract: Embodiments of this invention relate to a processing chamber and methods of distributing reactants therein to facilitate cyclical layer deposition of films on a substrate. One embodiment of a substrate processing chamber includes a chamber body and a substrate support disposed in the chamber body. A lid is disposed on the chamber body. An injection plate having a recess is mounted on the lid. A bottom surface of the recess has a plurality of apertures limited to an area proximate a central portion of the substrate receiving surface of the substrate support. Another embodiment of a substrate processing chamber includes a chamber body having interior sidewalls and an interior bottom wall. A top liner is disposed along the interior sidewalls of the chamber body. A bottom liner is disposed on the interior bottom wall of the chamber body. A gap is defined between the top liner and the bottom liner to allow a purge gas to be introduced therethrough.

Abstract: An apparatus for cyclical depositing of thin films on semiconductor substrates, comprising a process chamber having a gas distribution system with separate paths for process gases and an exhaust system synchronized with operation of valves dosing the process gases into a reaction region of the chamber.

Abstract: An improved plasma applicator for remotely generating a plasma for use in semiconductor manufacturing is provided. In one embodiment, a plasma applicator is comprised of a chamber assembly, a removable waveguide adapter and a circular clamp which secures the adapter to the chamber assembly. The chamber assembly includes an aperture plate, a microwave transparent window, a chamber body and a microwave sensor which is mounted on the chamber body. The chamber body has a proximate end opening adapted to admit microwave energy into the cavity and a distal end disposed generally on the opposite side of the cavity from the proximate end opening. The chamber body further has a gas outlet port adapted to permit the flow of an excited gas out of the cavity and a gas inlet port adapted to admit a precursor gas into the cavity. The gas inlet port has a center axis which is disposed between the proximate end opening of the chamber body and the midpoint between the proximate end opening and the distal end of the body.

Abstract: In accordance with an embodiment of the invention, a processing chamber is configured to carry out chemical vapor deposition (CVD). An ampoule vaporizer is fastened to the chamber, and is configured to convert a fluorine-free tungsten-containing solid compound to vapor delivered to the chamber for use in the CVD. In one embodiment, the solid compound is tungsten hexacarbonyl (W(CO)6). In another embodiment, a mass flow controller is fastened to the chamber, and is configured to receive the vapor from the ampoule vaporizer, regulate the flow of the vapor, and deliver the vapor to the chamber. In yet another embodiment, the chamber includes a funnel-shaped dispersion plate configured to receive a gas mixture and direct the gas mixture toward a surface of the wafer in a substantially uniform manner.

Abstract: A substrate support assembly for supporting a substrate during processing is provided. In one embodiment, a support assembly includes a ceramic body having an embedded heating element and a base plate. The base plate and the ceramic body define a channel therebetween adapted to supply purge gas to a perimeter of a substrate disposed on the support assembly. The base plate is fastened to the body by brazing, adhering, fastening, press fitting or by mating engaging portions of a retention device such as a bayonet fitting.

Abstract: A showerhead assembly for distributing gases within a processing chamber is provided. In one embodiment, the showerhead assembly includes a cylindrical member having a faceplate coupled thereto. The cylindrical member has an outwardly extending first flange at a first end. The faceplate is coupled to a second end of the cylindrical member and has a plurality of holes formed though a center region of the faceplate. The joint between the cylindrical member and the faceplate allow for relative movement when subjected to thermal stresses. In another embodiment, at least one clamp member retains the faceplate to the second end of the cylindrical member.

Abstract: Embodiments of the present invention generally relate to an apparatus and method for delivering two separate gas flows to a processing region. One embodiment of a substrate processing chamber adapted to deliver two separate gas flows to a processing region comprises a substrate support having a substrate receiving surface and a showerhead disposed over the substrate receiving surface. The showerhead includes a first passageway having a plurality of first passageway holes and a second passageway having a plurality of second passageway holes. The first passageway is adapted to deliver a first gas flow through the first passageway holes to the substrate receiving surface. The second passageway is adapted to deliver a second gas flow through the second passageway holes to the substrate receiving surface. The substrate processing chamber further includes a plasma power source.

Abstract: A temperature-controlled exhaust assembly with cold trap capability. One embodiment of the exhaust assembly comprises a multi-heater design which allows for independent multi-zone closed-loop temperature control. Another embodiment comprises a compact multi-valve uni-body design incorporating a single heater for simplified closed-loop temperature control. The cold trap incorporates a heater for temperature control at the inlet of the trap to minimize undesirable deposits. One embodiment also comprises a multi-stage cold trap and a particle trap. As a removable unit, this cold trap provides additional safety in the handling and disposal of the adsorbed condensables.

Abstract: A lid assembly for a semiconductor processing system is provided. The lid assembly generally includes a lid having a gas manifold mounted on a first side and a baffle plate mounted on a second side. The gas manifold is configured to deliver a plurality of gases to a plenum defined between the baffle plate and the lid. The gases are mixed within a recess formed in the baffle plate before exiting into the processing system through a singular passage.

Abstract: A set of lift pins defines a storage location for a substrate in a substrate processing chamber. Each lift pin has an actuating mechanism including a translating mechanism that translates vertical actuation into horizontal motion. The actuating mechanism may include a base, a mechanism adapted to raise and lower the base, and a lever pivotally mounted on the base. The lift pin may be fixedly mounted on the lever. A stop may be adjacent the base and adapted to engage the lever to pivot the lever as the base is lowered.

Abstract: A showerhead for distributing gases in a semiconductor process chamber. In one embodiment, a showerhead comprising a perforated center portion, a mounting portion circumscribing the perforated center portion and a plurality of bosses extending from the mounting portion each having a hole disposed therethrough is provided. Another embodiment of the invention provides a showerhead that includes a mounting portion having a first side circumscribing a perforated center portion. A ring extends from the first side of the mounting portion. A plurality of mounting holes are disposed in the mounting portion radially to either side of the ring. The showerhead provides controlled thermal transfer between the showerhead and chamber lid resulting in less deposition on the showerhead.

Abstract: An apparatus for wafer processing, which comprises a chamber body and a heated liner which are thermally isolated from each other by isolating pins. During wafer processing, e.g., deposition of titanium nitride film by thermal reaction between titanium tetrachloride and ammonia, a wafer substrate is heated to a reaction temperature in the range of 600-700° C. by a heated support pedestal. The chamber liner and the interior chamber walls are maintained at a temperature between 150-250° C. to prevent deposition of undesirable by-products inside the chamber. This facilitates the chamber cleaning procedure, which can be performed using an in-situ chlorine-based process. The excellent thermal isolation between the heated liner and the chamber body allows the chamber exterior to be maintained at a safe operating temperature of 60-65° C. A heated exhaust assembly is also used in conjunction with the process chamber to remove exhaust gases and reaction by-products.

Abstract: An apparatus for wafer processing, which comprises a chamber body and a heated liner which are thermally isolated from each other by isolating pins. During wafer processing, e.g., deposition of titanium nitride film by thermal reaction between titanium tetrachloride and ammonia, a wafer substrate is heated to a reaction temperature in the range of 600-700° C. by a heated support pedestal. The chamber liner and the interior chamber walls are maintained at a temperature between 150-250° C. to prevent deposition of undesirable by-products inside the chamber. This facilitates the chamber cleaning procedure, which can be performed using an in-situ chlorine-based process. The excellent thermal isolation between the heated liner and the chamber body allows the chamber exterior to be maintained at a safe operating temperature of 60-65° C. A heated exhaust assembly is also used in conjunction with the process chamber to remove exhaust gases and reaction by-products.