Patents by Inventor Gary Dickerson

Gary Dickerson has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).

  • Patent number: 10943779
    Abstract: Embodiments include methods and systems of 3D structure fill. In one embodiment, a method of filling a trench in a wafer includes performing directional plasma treatment with an ion beam at an angle with respect to a sidewall of the trench to form a treated portion of the sidewall and an untreated bottom of the trench. A material is deposited in the trench. The deposition rate of the material on the treated portion of the sidewall is different than a second deposition rate on the untreated bottom of the trench. In one embodiment, a method includes depositing a material on the wafer, filling a bottom of the trench and forming a layer on a sidewall of the trench and a top surface adjacent to the trench. The method includes etching the layer with an ion beam at an angle with respect to the sidewall.
    Type: Grant
    Filed: November 18, 2016
    Date of Patent: March 9, 2021
    Assignee: Applied Materials, Inc.
    Inventors: Ellie Yieh, Ludovic Godet, Srinivas Nemani, Er-Xuan Ping, Gary Dickerson
  • Patent number: 10377665
    Abstract: Embodiments of the disclosure provide an apparatus and methods for localized stress modulation for overlay and substrate distortion using electron or ion implantation directly to a glass substrate. In one embodiment, a process for modifying a bulk property of a glass substrate generally includes identifying a stress pattern of a glass substrate, determining doping parameters to correct a defect (e.g., overlay error or substrate distortion) based on the stress pattern, and providing a treatment recipe to a treatment tool, wherein the treatment recipe is formulated according to the doping parameters. The process may further include performing a doping treatment process on the glass substrate using the treatment recipe to correct the overlay error or substrate distortion. In some embodiments, the treatment recipe is determined by comparing the stress pattern with a database library containing data correlating stress changes in glass substrates to various doping parameters.
    Type: Grant
    Filed: January 14, 2016
    Date of Patent: August 13, 2019
    Assignee: VARIAN SEMICONDUCTOR EQUIPMENT ASSOCIATES, INC.
    Inventors: Joseph C. Olson, Ludovic Godet, Gary Dickerson
  • Publication number: 20170144929
    Abstract: Embodiments of the disclosure provide an apparatus and methods for localized stress modulation for overlay and substrate distortion using electron or ion implantation directly to a glass substrate. In one embodiment, a process for modifying a bulk property of a glass substrate generally includes identifying a stress pattern of a glass substrate, determining doping parameters to correct a defect (e.g., overlay error or substrate distortion) based on the stress pattern, and providing a treatment recipe to a treatment tool, wherein the treatment recipe is formulated according to the doping parameters. The process may further include performing a doping treatment process on the glass substrate using the treatment recipe to correct the overlay error or substrate distortion. In some embodiments, the treatment recipe is determined by comparing the stress pattern with a database library containing data correlating stress changes in glass substrates to various doping parameters.
    Type: Application
    Filed: January 14, 2016
    Publication date: May 25, 2017
    Inventors: Joseph C. Olson, Ludovic Godet, Gary Dickerson
  • Publication number: 20170069488
    Abstract: Embodiments include methods and systems of 3D structure fill. In one embodiment, a method of filling a trench in a wafer includes performing directional plasma treatment with an ion beam at an angle with respect to a sidewall of the trench to form a treated portion of the sidewall and an untreated bottom of the trench. A material is deposited in the trench. The deposition rate of the material on the treated portion of the sidewall is different than a second deposition rate on the untreated bottom of the trench. In one embodiment, a method includes depositing a material on the wafer, filling a bottom of the trench and forming a layer on a sidewall of the trench and a top surface adjacent to the trench. The method includes etching the layer with an ion beam at an angle with respect to the sidewall.
    Type: Application
    Filed: November 18, 2016
    Publication date: March 9, 2017
    Inventors: Ellie Yieh, Ludovic Godet, Srinivas Nemani, Er-Xuan Ping, Gary Dickerson
  • Patent number: 9530674
    Abstract: Embodiments include methods and systems of 3D structure fill. In one embodiment, a method of filling a trench in a wafer includes performing directional plasma treatment with an ion beam at an angle with respect to a sidewall of the trench to form a treated portion of the sidewall and an untreated bottom of the trench. A material is deposited in the trench. The deposition rate of the material on the treated portion of the sidewall is different than a second deposition rate on the untreated bottom of the trench. In one embodiment, a method includes depositing a material on the wafer, filling a bottom of the trench and forming a layer on a sidewall of the trench and a top surface adjacent to the trench. The method includes etching the layer with an ion beam at an angle with respect to the sidewall.
    Type: Grant
    Filed: October 2, 2013
    Date of Patent: December 27, 2016
    Assignee: Applied Materials, Inc.
    Inventors: Ellie Yieh, Ludovic Godet, Srinivas Nemani, Er-Xuan Ping, Gary Dickerson
  • Publication number: 20150093907
    Abstract: Embodiments include methods and systems of 3D structure fill. In one embodiment, a method of filling a trench in a wafer includes performing directional plasma treatment with an ion beam at an angle with respect to a sidewall of the trench to form a treated portion of the sidewall and an untreated bottom of the trench. A material is deposited in the trench. The deposition rate of the material on the treated portion of the sidewall is different than a second deposition rate on the untreated bottom of the trench. In one embodiment, a method includes depositing a material on the wafer, filling a bottom of the trench and forming a layer on a sidewall of the trench and a top surface adjacent to the trench. The method includes etching the layer with an ion beam at an angle with respect to the sidewall.
    Type: Application
    Filed: October 2, 2013
    Publication date: April 2, 2015
    Inventors: Ellie YIEH, Ludovic Godet, Srinivas Nemani, Er-Xuan Ping, Gary Dickerson
  • Patent number: 7355709
    Abstract: Methods and systems for measurements of a substrate are provided. One system includes a non-optical subsystem configured to perform first measurements on a substrate. The system also includes an optical subsystem coupled to the non-optical subsystem. The optical subsystem is configured to perform second measurements on the substrate. In addition, the system includes a processor coupled to the subsystems. The processor is configured to calibrate one of the subsystems using the measurements performed by the other subsystem. One method includes performing first measurements on a substrate using a non-optical subsystem and performing second measurements on the substrate using an optical subsystem that is coupled to the non-optical subsystem. The method also includes calibrating one of the subsystems using the measurements performed by the other subsystem.
    Type: Grant
    Filed: February 22, 2005
    Date of Patent: April 8, 2008
    Assignee: KLA-Tencor Technologies Corp.
    Inventors: Christopher F. Bevis, Gary Dickerson