Abstract: A gas coupler is capable of conducting gas between a gas component, gas source and substrate processing chamber. The gas coupler comprises a metal block comprising a gas component seating surface having a plurality of gas component coupling ports. The block also has a plurality of sidewalls at right angles to the gas component seating surface, each sidewall comprising a counterbored gas orifice. A plurality of right-angled internal passageways are each connected to a gas component coupling port. Each internal passageway terminates at counterbored gas orifice on a different sidewall surface so that each gas component coupling port is fluidly connected to a different sidewall.

Abstract: A method and apparatus are provided for measuring the thickness of a test object. The apparatus includes an eddy current sensor having first and second sensor heads. The sensor heads are positioned to have a predetermined gap therebetween for passage by at least a portion of the test object through the gap. The sensor heads make measurements at given sampling locations on the test object as the test object is moved through the gap. The apparatus also includes a position sensing mechanism to determine positions of the sampling locations on the test object. The apparatus also includes an evaluation circuit in communication with the eddy current sensor and to the position sensing mechanism for determining the thickness of the test object at the sampling locations.

Abstract: A method and apparatus are provided for measuring the thickness of a test object. The apparatus includes an eddy current sensor having first and second sensor heads. The sensor heads are positioned to have a predetermined gap therebetween for passage by at least a portion of the test object through the gap. The sensor heads make measurements at given sampling locations on the test object as the test object is moved through the gap. The apparatus also includes a position sensing mechanism to determine positions of the sampling locations on the test object. The apparatus also includes an evaluation circuit in communication with the eddy current sensor and to the position sensing mechanism for determining the thickness of the test object at the sampling locations.

Abstract: A method and apparatus are provided for measuring the thickness of a test object. The apparatus includes an eddy current sensor having first and second sensor heads. The sensor heads are positioned to have a predetermined gap therebetween for passage by at least a portion of the test object through the gap. The sensor heads make measurements at given sampling locations on the test object as the test object is moved through the gap. The apparatus also includes a position sensing mechanism to determine positions of the sampling locations on the test object. The apparatus also includes an evaluation circuit in communication with the eddy current sensor and to the position sensing mechanism for determining the thickness of the test object at the sampling locations.

Abstract: A gas coupler is capable of conducting gas between a gas component, gas source and substrate processing chamber. The gas coupler comprises a metal block comprising a gas component seating surface having a plurality of gas component coupling ports. The block also has a plurality of sidewalls at right angles to the gas component seating surface, each sidewall comprising a counterbored gas orifice. A plurality of right-angled internal passageways are each connected to a gas component coupling port. Each internal passageway terminates at counterbored gas orifice on a different sidewall surface so that each gas component coupling port is fluidly connected to a different sidewall.

Abstract: A method and apparatus are provided for measuring the thickness of a test object. The apparatus includes an eddy current sensor having first and second sensor heads. The sensor heads are positioned to have a predetermined gap therebetween for passage by at least a portion of the test object through the gap. The sensor heads make measurements at given sampling locations on the test object as the test object is moved through the gap. The apparatus also includes a position sensing mechanism to determine positions of the sampling locations on the test object. The apparatus also includes an evaluation circuit in communication with the eddy current sensor and to the position sensing mechanism for determining the thickness of the test object at the sampling locations.

Abstract: A method and apparatus are provided for measuring the thickness of a test object. The apparatus includes an eddy current sensor having first and second sensor heads. The sensor heads are positioned to have a predetermined gap therebetween for passage by at least a portion of the test object through the gap. The sensor heads make measurements at given sampling locations on the test object as the test object is moved through the gap. The apparatus also includes a position sensing mechanism to determine positions of the sampling locations on the test object. The apparatus also includes an evaluation circuit in communication with the eddy current sensor and to the position sensing mechanism for determining the thickness of the test object at the sampling locations.

Abstract: A method and apparatus for removing native oxides from a substrate surface is provided. In one aspect, the chamber comprises a chamber body and a support assembly at least partially disposed within the chamber body and adapted to support a substrate thereon. The support assembly includes one or more fluid channels at least partially formed therein and capable of cooling the substrate. The chamber further comprises a lid assembly disposed on an upper surface of the chamber body. The lid assembly includes a first electrode and a second electrode which define a plasma cavity therebetween, wherein the second electrode is adapted to connectively heat the substrate.

Abstract: A substrate support assembly and method for supporting a substrate are provided. In at least one embodiment, the support assembly includes a body having one or more fluid conduits disposed therethrough, and a support member disposed on a first end of the body. The support member includes one or more fluid channels formed in an upper surface thereof, wherein each fluid channel is in communication with the one or more of the fluid conduits. The support assembly also includes a cooling medium source in fluid communication with the one or more fluid conduits, and a first electrode having a plurality of holes formed therethrough. The first electrode is disposed on the upper surface of the support member such that each of the plurality of holes is in fluid communication with at least one of the one or more fluid channels formed in the upper surface of the support member.

Abstract: A lid assembly for semiconductor processing is provided. In at least one embodiment, the lid assembly includes a first electrode comprising an expanding section that has a gradually increasing inner diameter. The lid assembly also includes a second electrode disposed opposite the first electrode. A plasma cavity is defined between the inner diameter of the expanding section of the first electrode and a first surface of the second electrode.

Abstract: A method for removing native oxides from a substrate surface is provided. In at least one embodiment, the method includes supporting the substrate surface in a vacuum chamber and generating reactive species from a gas mixture within the chamber. The substrate surface is then cooled within the chamber and the reactive species are directed to the cooled substrate surface to react with the native oxides thereon and form a film on the substrate surface. The substrate surface is then heated within the chamber to vaporize the film.

Abstract: A method and apparatus are provided for measuring the thickness of a test object. The apparatus includes an eddy current sensor having first and second sensor heads. The sensor heads are positioned to have a predetermined gap therebetween for passage by at least a portion of the test object through the gap. The sensor heads make measurements at given sampling locations on the test object as the test object is moved through the gap. The apparatus also includes a position sensing mechanism to determine positions of the sampling locations on the test object. The apparatus also includes an evaluation circuit in communication with the eddy current sensor and to the position sensing mechanism for determining the thickness of the test object at the sampling locations.

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: 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.

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 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 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.