Patents by Inventor J. Joseph Armstrong
J. Joseph Armstrong 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).
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Patent number: 11715615Abstract: A light modulated electron source utilizes a photon-beam source to modulate the emission current of an electron beam emitted from a silicon-based field emitter. The field emitter's cathode includes a protrusion fabricated on a silicon substrate and having an emission tip covered by a coating layer. An extractor generates an electric field that attracts free electrons toward the emission tip for emission as part of the electron beam. The photon-beam source generates a photon beam including photons having an energy greater than the bandgap of silicon, and includes optics that direct the photon beam onto the emission tip, whereby each absorbed photon creates a photo-electron that combines with the free electrons to enhance the electron beam's emission current. A controller modulates the emission current by controlling the intensity of the photon beam applied to the emission tip. A monitor measures the electron beam and provides feedback to the controller.Type: GrantFiled: July 6, 2022Date of Patent: August 1, 2023Assignee: KLA CorporationInventors: Edgardo Garcia Berrios, J. Joseph Armstrong, Yinying Xiao-Li, John Fielden, Yung-Ho Alex Chuang
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Publication number: 20220336180Abstract: A light modulated electron source utilizes a photon-beam source to modulate the emission current of an electron beam emitted from a silicon-based field emitter. The field emitter's cathode includes a protrusion fabricated on a silicon substrate and having an emission tip covered by a coating layer. An extractor generates an electric field that attracts free electrons toward the emission tip for emission as part of the electron beam. The photon-beam source generates a photon beam including photons having an energy greater than the bandgap of silicon, and includes optics that direct the photon beam onto the emission tip, whereby each absorbed photon creates a photo-electron that combines with the free electrons to enhance the electron beam's emission current. A controller modulates the emission current by controlling the intensity of the photon beam applied to the emission tip. A monitor measures the electron beam and provides feedback to the controller.Type: ApplicationFiled: July 6, 2022Publication date: October 20, 2022Inventors: Edgardo Garcia Berrios, J. Joseph Armstrong, Yinying Xiao-Li, John Fielden, Yung-Ho Alex Chuang
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Patent number: 11417492Abstract: A light modulated electron source utilizes a photon-beam source to modulate the emission current of an electron beam emitted from a silicon-based field emitter. The field emitter's cathode includes a protrusion fabricated on a silicon substrate and having an emission tip covered by a coating layer. An extractor generates an electric field that attracts free electrons toward the emission tip for emission as part of the electron beam. The photon-beam source generates a photon beam including photons having an energy greater than the bandgap of silicon, and includes optics that direct the photon beam onto the emission tip, whereby each absorbed photon creates a photo-electron that combines with the free electrons to enhance the electron beam's emission current. A controller modulates the emission current by controlling the intensity of the photon beam applied to the emission tip. A monitor measures the electron beam and provides feedback to the controller.Type: GrantFiled: September 14, 2020Date of Patent: August 16, 2022Assignee: KLA CorporationInventors: Edgardo Garcia Berrios, J. Joseph Armstrong, Yinying Xiao-Li, John Fielden, Yung-Ho Alex Chuang
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Publication number: 20210098222Abstract: A light modulated electron source utilizes a photon-beam source to modulate the emission current of an electron beam emitted from a silicon-based field emitter. The field emitter's cathode includes a protrusion fabricated on a silicon substrate and having an emission tip covered by a coating layer. An extractor generates an electric field that attracts free electrons toward the emission tip for emission as part of the electron beam. The photon-beam source generates a photon beam including photons having an energy greater than the bandgap of silicon, and includes optics that direct the photon beam onto the emission tip, whereby each absorbed photon creates a photo-electron that combines with the free electrons to enhance the electron beam's emission current. A controller modulates the emission current by controlling the intensity of the photon beam applied to the emission tip. A monitor measures the electron beam and provides feedback to the controller.Type: ApplicationFiled: September 14, 2020Publication date: April 1, 2021Inventors: Edgardo Garcia Berrios, J. Joseph Armstrong, Yinying Xiao-Li, John Fielden, Yung-Ho Alex Chuang
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Patent number: 10439355Abstract: An optical inspection system that utilizes sub-200 nm incident light beam to inspect a surface of an object for defects is described. The sub-200 nm incident light beam is generated by combining first light having a wavelength of about 1109 nm with second light having a wavelength of approximately 234 nm. An optical system includes optical components configured to direct the incident light beam to a surface of the object, and image relay optics are configured to collect and relay at least two channels of light to a sensor, where at least one channel includes light reflected from the object, and at least one channel includes light transmitted through the object. The sensor is configured to simultaneously detect both the reflected and transmitted light. A laser for generating the sub-200 nm incident light beam includes a fundamental laser, two or more harmonic generators, a frequency doubler and a two frequency mixing stages.Type: GrantFiled: February 21, 2018Date of Patent: October 8, 2019Assignee: KLA-Tencor CorporationInventors: Yung-Ho Chuang, J. Joseph Armstrong, Yujun Deng, Justin Dianhuan Liou, Vladimir Dribinski, John Fielden
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Patent number: 10199149Abstract: A laser assembly for generating laser output light at an output wavelength of approximately 183 nm includes a fundamental laser, an optical parametric system (OPS), a fifth harmonic generator, and a frequency mixing module. The fundamental laser generates fundamental light at a fundamental frequency. The OPS generates a down-converted signal at a down-converted frequency. The fifth harmonic generator generates a fifth harmonic of the fundamental light. The frequency mixing module mixes the down-converted signal and the fifth harmonic to produce the laser output light at a frequency equal to a sum of the fifth harmonic frequency and the down-converted frequency. The OPS generates the down-converted signal by generating a down-converted seed signal at the down-converted frequency, and then mixing the down-converted seed signal with a portion of the fundamental light.Type: GrantFiled: July 26, 2017Date of Patent: February 5, 2019Assignee: KLA-Tencor CorporationInventors: Yung-Ho Alex Chuang, J. Joseph Armstrong, Yujun Deng, Vladimir Dribinski, John Fielden, Jidong Zhang
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Patent number: 10193293Abstract: A pulse multiplier includes a polarizing beam splitter, a wave plate, and a set of multi-surface reflecting components (e.g., one or more etalons and one or more mirrors). The polarizing beam splitter passes input laser pulses through the wave plate to the multi-surface reflecting components, which reflect portions of each input laser pulse back through the wave plate to the polarizing beam splitter. The polarizing beam splitter reflects each reflected portion to form an output of the pulse multiplier. The multi-surface reflecting components are configured such that the output pulses exiting the pulse multiplier have an output repetition pulse frequency rate that is at least double the input repetition pulse frequency.Type: GrantFiled: April 9, 2018Date of Patent: January 29, 2019Assignee: KLA-Tencor CorporationInventors: Yung-Ho Chuang, J. Joseph Armstrong, Justin Dianhuan Liou, Vladimir Dribinski, David L. Brown
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Publication number: 20180233872Abstract: A pulse multiplier includes a polarizing beam splitter, a wave plate, and a set of multi-surface reflecting components (e.g., one or more etalons and one or more mirrors). The polarizing beam splitter passes input laser pulses through the wave plate to the multi-surface reflecting components, which reflect portions of each input laser pulse back through the wave plate to the polarizing beam splitter. The polarizing beam splitter reflects each reflected portion to form an output of the pulse multiplier. The multi-surface reflecting components are configured such that the output pulses exiting the pulse multiplier have an output repetition pulse frequency rate that is at least double the input repetition pulse frequency.Type: ApplicationFiled: April 9, 2018Publication date: August 16, 2018Inventors: Yung-Ho Chuang, J. Joseph Armstrong, Justin Dianhuan Liou, Vladimir Dribinski, David L. Brown
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Patent number: 10044164Abstract: A repetition rate (pulse) multiplier includes one or more beam splitters and prisms forming one or more ring cavities with different optical path lengths that delay parts of the energy of each pulse. A series of input laser pulses circulate in the ring cavities and part of the energy of each pulse leaves the system after traversing the shorter cavity path, while another part of the energy leaves the system after traversing the longer cavity path, and/or a combination of both cavity paths. By proper choice of the ring cavity optical path length, the repetition rate of an output series of laser pulses can be made to be a multiple of the input repetition rate. The relative energies of the output pulses can be controlled by choosing the transmission and reflection coefficients of the beam splitters. Some embodiments generate a time-averaged output beam profile that is substantially flat in one dimension.Type: GrantFiled: August 17, 2016Date of Patent: August 7, 2018Assignee: KLA-Tencor CorporationInventors: Yung-Ho Alex Chuang, Xiaoxu Lu, Justin Dianhuan Liou, J. Joseph Armstrong, Yujun Deng, John Fielden
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Publication number: 20180191126Abstract: An optical inspection system that utilizes sub-200 nm incident light beam to inspect a surface of an object for defects is described. The sub-200 nm incident light beam is generated by combining first light having a wavelength of about 1109 nm with second light having a wavelength of approximately 234 nm. An optical system includes optical components configured to direct the incident light beam to a surface of the object, and image relay optics are configured to collect and relay at least two channels of light to a sensor, where at least one channel includes light reflected from the object, and at least one channel includes light transmitted through the object. The sensor is configured to simultaneously detect both the reflected and transmitted light. A laser for generating the sub-200 nm incident light beam includes a fundamental laser, two or more harmonic generators, a frequency doubler and a two frequency mixing stages.Type: ApplicationFiled: February 21, 2018Publication date: July 5, 2018Inventors: Yung-Ho Chuang, J. Joseph Armstrong, Yujun Deng, Justin Dianhuan Liou, Vladimir Dribinski, John Fielden
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Patent number: 9972959Abstract: A pulse multiplier includes a polarizing beam splitter, a wave plate, and a set of multi-surface reflecting components (e.g., one or more etalons and one or more mirrors). The polarizing beam splitter passes input laser pulses through the wave plate to the multi-surface reflecting components, which reflect portions of each input laser pulse back through the wave plate to the polarizing beam splitter. The polarizing beam splitter reflects each reflected portion to form an output of the pulse multiplier. The multi-surface reflecting components are configured such that the output pulses exiting the pulse multiplier have an output repetition pulse frequency rate that is at least double the input repetition pulse frequency.Type: GrantFiled: June 8, 2016Date of Patent: May 15, 2018Assignee: KLA-Tencor CorporationInventors: Yung-Ho Chuang, J. Joseph Armstrong, Justin Dianhuan Liou, Vladimir Dribinski, David L. Brown
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Patent number: 9935421Abstract: An improved solid-state laser for generating sub-200 nm light is described. This laser uses a fundamental wavelength between about 1030 nm and 1065 nm to generate the sub-200 nm light. The final frequency conversion stage of the laser creates the sub-200 nm light by mixing a wavelength of approximately 1109 nm with a wavelength of approximately 234 nm. By proper selection of non-linear media, such mixing can be achieved by nearly non-critical phase matching. This mixing results in high conversion efficiency, good stability, and high reliability.Type: GrantFiled: November 4, 2016Date of Patent: April 3, 2018Assignee: KLA-Tencor CorporationInventors: Yung-Ho Chuang, J. Joseph Armstrong, Yujun Deng, Justin Dianhuan Liou, Vladimir Dribinski, John Fielden
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Publication number: 20170323716Abstract: A laser assembly for generating laser output light at an output wavelength of approximately 183 nm includes a fundamental laser, an optical parametric system (OPS), a fifth harmonic generator, and a frequency mixing module. The fundamental laser generates fundamental light at a fundamental frequency. The OPS generates a down-converted signal at a down-converted frequency. The fifth harmonic generator generates a fifth harmonic of the fundamental light. The frequency mixing module mixes the down-converted signal and the fifth harmonic to produce the laser output light at a frequency equal to a sum of the fifth harmonic frequency and the down-converted frequency. The OPS generates the down-converted signal by generating a down-converted seed signal at the down-converted frequency, and then mixing the down-converted seed signal with a portion of the fundamental light.Type: ApplicationFiled: July 26, 2017Publication date: November 9, 2017Inventors: Yung-Ho Alex Chuang, J. Joseph Armstrong, Yujun Deng, Vladimir Dribinski, John Fielden, Jidong Zhang
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Patent number: 9793673Abstract: A pulse multiplier includes a polarizing beam splitter, a wave plate, and a set of mirrors. The polarizing beam splitter receives an input laser pulse. The wave plate receives light from the polarized beam splitter and generates a first set of pulses and a second set of pulses. The first set of pulses has a different polarization than the second set of pulses. The polarizing beam splitter, the wave plate, and the set of mirrors create a ring cavity. The polarizing beam splitter transmits the first set of pulses as an output of the pulse multiplier and reflects the second set of pulses into the ring cavity. This pulse multiplier can inexpensively reduce the peak power per pulse while increasing the number of pulses per second with minimal total power loss.Type: GrantFiled: June 1, 2012Date of Patent: October 17, 2017Assignee: KLA-Tencor CorporationInventors: Yung-Ho Chuang, J. Joseph Armstrong, Justin Dianhuan Liou, Vladimir Dribinski, David L. Brown
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Patent number: 9768577Abstract: A pulse multiplier includes a beam splitter and one or more mirrors. The beam splitter receives a series of input laser pulses and directs part of the energy of each pulse into a ring cavity. After circulating around the ring cavity, part of the pulse energy leaves the ring cavity through the beam splitter and part of the energy is recirculated. By selecting the ring cavity optical path length, the repetition rate of an output series of laser pulses can be made to be a multiple of the input repetition rate. The relative energies of the output pulses can be controlled by choosing the transmission and reflection coefficients of the beam splitter. This pulse multiplier can inexpensively reduce the peak power per pulse while increasing the number of pulses per second with minimal total power loss.Type: GrantFiled: August 21, 2015Date of Patent: September 19, 2017Assignee: KLA-Tencor CorporationInventors: Yung-Ho Alex Chuang, Justin Dianhuan Liou, J. Joseph Armstrong, Yujun Deng
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Patent number: 9753352Abstract: The present invention includes a fundamental laser light source configured to generate fundamental wavelength laser light, a first nonlinear optical crystal configured to generate first alternate wavelength light, a second nonlinear optical crystal configured to generate second alternate wavelength light, a set of Brewster angle wavefront processing optics configured to condition the first and second alternate wavelengths of light, and a harmonic separator configured to receive the first alternate wavelength light and the second alternate wavelength light from the set of Brewster angle wavefront processing optics, the harmonic separator configured to at least partially separate the first alternate wavelength light from the second alternate wavelength light.Type: GrantFiled: August 28, 2015Date of Patent: September 5, 2017Assignee: KLA-Tencor CorporationInventor: J. Joseph Armstrong
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Patent number: 9748729Abstract: A laser assembly for generating laser output light at an output wavelength of approximately 183 nm includes a fundamental laser, an optical parametric system (OPS), a fifth harmonic generator, and a frequency mixing module. The fundamental laser generates fundamental light at a fundamental frequency. The OPS generates a down-converted signal at a down-converted frequency. The fifth harmonic generator generates a fifth harmonic of the fundamental light. The frequency mixing module mixes the down-converted signal and the fifth harmonic to produce the laser output light at a frequency equal to a sum of the fifth harmonic frequency and the down-converted frequency. The OPS generates the down-converted signal by generating a down-converted seed signal at the down-converted frequency, and then mixing the down-converted seed signal with a portion of the fundamental light.Type: GrantFiled: October 1, 2015Date of Patent: August 29, 2017Assignee: KLA-Tencor CorporationInventors: Yung-Ho Alex Chuang, J. Joseph Armstrong, Yujun Deng, Vladimir Dribinski, John Fielden, Jidong Zhang
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Publication number: 20170229829Abstract: Laser and inspection systems that generate laser output light at sub-200 nm wavelengths using fundamental light at approximately 1064 nm. A second harmonic generator module generates second harmonic light directed to both an optical parametric (OP) module, which generates down-converted signal (idler light), and to a fifth harmonic generator module, which generates fifth harmonic light. The OP module includes an optical parametric oscillator that is configured to generate the idler signal at approximately 0.5 times the fundamental frequency. The idler light and fifth harmonic light are then mixed by a frequency mixing module to generate the laser output light having an output frequency equal to approximately 5.5 times the fundamental frequency.Type: ApplicationFiled: April 24, 2017Publication date: August 10, 2017Inventors: Yung-Ho Alex Chuang, J. Joseph Armstrong, Vladimir Dribinski, John Fielden
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Patent number: 9608399Abstract: An improved laser uses a pump laser with a wavelength near 1109 nm and a fundamental wavelength near 1171 nm to generate light at a wavelength between approximately 189 nm and approximately 200 nm, e.g. 193 nm. The laser mixes the 1109 nm pump wavelength with the 5th harmonic of the 1171 nm fundamental, which is at a wavelength of approximately 234.2 nm. By proper selection of non-linear media, such mixing can be achieved by nearly non-critical phase matching. This mixing results in high conversion efficiency, good stability, and high reliability.Type: GrantFiled: March 13, 2014Date of Patent: March 28, 2017Assignee: KLA-Tencor CorporationInventors: Yung-Ho Chuang, J. Joseph Armstrong, Justin Dianhuan Liou, Vladimir Dribinski, John Fielden
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Publication number: 20170063026Abstract: An improved solid-state laser for generating sub-200 nm light is described. This laser uses a fundamental wavelength between about 1030 nm and 1065 nm to generate the sub-200 nm light. The final frequency conversion stage of the laser creates the sub-200 nm light by mixing a wavelength of approximately 1109 nm with a wavelength of approximately 234 nm. By proper selection of non-linear media, such mixing can be achieved by nearly non-critical phase matching. This mixing results in high conversion efficiency, good stability, and high reliability.Type: ApplicationFiled: November 4, 2016Publication date: March 2, 2017Inventors: Yung-Ho Chuang, J. Joseph Armstrong, Yujun Deng, Justin Dianhuan Liou, Vladimir Dribinski, John Fielden