Patents by Inventor Roy D. McGregor
Roy D. McGregor 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: 6912267Abstract: A laser-plasma EUV radiation source (10) that employs one or more approaches for preventing vaporization of material from a nozzle assembly (40) of the source (10) by electrical discharge from the plasma (30). The first approach includes employing an electrically isolating nozzle end, such as a glass capillary tube (46). The tube (46) extends beyond all of the conductive surfaces of the nozzle assembly (40) by a suitable distance so that the pressure around the closest conducting portion of the nozzle assembly (40) is low enough not to support arcing. A second approach includes providing electrical isolation of the conductive portions of the source (40) from the vacuum chamber wall. A third approach includes applying a bias potential (52) to the nozzle assembly (40) to raise the potential of the nozzle assembly (40) to the potential of the arc.Type: GrantFiled: November 6, 2002Date of Patent: June 28, 2005Assignee: University of Central Florida Research FoundationInventors: Rocco A. Orsini, Michael B. Petach, Mark E. Michaelian, Henry Shields, Roy D. McGregor, Steven W. Fornaca
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Patent number: 6864497Abstract: An EUV radiation source that creates a stable solid target filament. The source includes a nozzle assembly having a condenser chamber for cryogenically cooling a gaseous target material into a liquid state. The liquid target material is forced through an orifice of a target filament generator into an evaporation chamber as a liquid target stream. The evaporation chamber has a higher pressure than a vacuum process chamber of the source to allow the liquid target material to freeze into a target filament in a stable manner. The frozen target filament is emitted from the evaporation chamber into the process chamber as a stable target filament towards a target area. The higher pressure in the evaporation chamber can be the result of the evaporative cooling of the target material alone or in combination with a supplemental gas.Type: GrantFiled: December 11, 2002Date of Patent: March 8, 2005Assignee: University of Central Florida Research FoundationInventors: Rocco A. Orsini, Michael B. Petach, Roy D. McGregor
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Patent number: 6835944Abstract: An EUV radiation source that creates a stable solid filament target. The source includes a nozzle assembly having a condenser chamber for cryogenically cooling a gaseous target material into a liquid state. The liquid target material is filtered by a filter and sent to a holding chamber under pressure. The holding chamber allows entrained gas bubbles in the target material to be condensed into liquid prior to the filament target being emitted from the nozzle assembly. The target material is forced through a nozzle outlet tube to be emitted from the nozzle assembly as a liquid target stream. A thermal shield is provided around the outlet tube to maintain the liquid target material in the cryogenic state. The liquid target stream freezes and is vaporized by a laser beam from a laser source to generate the EUV radiation.Type: GrantFiled: October 11, 2002Date of Patent: December 28, 2004Assignee: University of Central Florida Research FoundationInventors: Rocco A. Orsini, Michael B. Petach, Mark E. Michaelian, Henry Shields, Roy D. McGregor, Steven W. Fornaca
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Publication number: 20040114720Abstract: An EUV radiation source that creates a stable solid target filament. The source includes a nozzle assembly having a condenser chamber for cryogenically cooling a gaseous target material into a liquid state. The liquid target material is forced through an orifice of a target filament generator into an evaporation chamber as a liquid target stream. The evaporation chamber has a higher pressure than a vacuum process chamber of the source to allow the liquid target material to freeze into a target filament in a stable manner. The frozen target filament is emitted from the evaporation chamber into the process chamber as a stable target filament towards a target area. The higher pressure in the evaporation chamber can be the result of the evaporative cooling of the target material alone or in combination with a supplemental gas.Type: ApplicationFiled: December 11, 2002Publication date: June 17, 2004Inventors: Rocco A. Orsini, Michael B. Petach, Roy D. McGregor
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Patent number: 6738452Abstract: A target material delivery system in the form of a nozzle (50) for an EUV radiation source (10). The nozzle (50) includes a target material supply line (66) having an orifice (68) through which droplets (76) of a liquid target material (64) are emitted, where the droplets (76) have a predetermined size, speed and spacing therebetween. The droplets (76) are mixed with a carrier gas (74) in a mixing chamber (54) enclosing the target material chamber (60) and the mixture of the droplets (76) and the carrier gas (74) enter a drift tube (56) from the mixing chamber (54). The droplets (76) are emitted into an accelerator chamber (124) from the drift tube (56) where the speed of the droplets (76) is increased to control the spacing therebetween. A vapor extractor (90) can be mounted to the accelerator chamber (124) or the drift tube (56) to remove the carrier gas (74) and target material vapor, which would otherwise adversely affect the EUV radiation generation.Type: GrantFiled: May 28, 2002Date of Patent: May 18, 2004Assignee: Northrop Grumman CorporationInventors: Roy D. McGregor, Robert A. Bunnell, Michael B. Petach, Rocco A. Orsini
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Publication number: 20040086080Abstract: A laser-plasma EUV radiation source (10) that employs one or more approaches for preventing vaporization of material from a nozzle assembly (40) of the source (10) by electrical discharge from the plasma (30). The first approach includes employing an electrically isolating nozzle end, such as a glass capillary tube (46). The tube (46) extends beyond all of the conductive surfaces of the nozzle assembly (40) by a suitable distance so that the pressure around the closest conducting portion of the nozzle assembly (40) is low enough not to support arcing. A second approach includes providing electrical isolation of the conductive portions of the source (40) from the vacuum chamber wall. A third approach includes applying a bias potential (52) to the nozzle assembly (40) to raise the potential of the nozzle assembly (40) to the potential of the arc.Type: ApplicationFiled: November 6, 2002Publication date: May 6, 2004Inventors: Rocco A. Orsini, Michael B. Petach, Mark E. Michaelian, Henry Shields, Roy D. McGregor, Steven W. Fornaca
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Publication number: 20040071266Abstract: An EUV radiation source that creates a stable solid filament target. The source includes a nozzle assembly having a condenser chamber for cryogenically cooling a gaseous target material into a liquid state. The liquid target material is filtered by a filter and sent to a holding chamber under pressure. The holding chamber allows entrained gas bubbles in the target material to be condensed into liquid prior to the filament target being emitted from the nozzle assembly. The target material is forced through a nozzle outlet tube to be emitted from the nozzle assembly as a liquid target stream. A thermal shield is provided around the outlet tube to maintain the liquid target material in the cryogenic state. The liquid target stream freezes and is vaporized by a laser beam from a laser source to generate the EUV radiation.Type: ApplicationFiled: October 11, 2002Publication date: April 15, 2004Inventors: Rocco A. Orsini, Michael B. Petach, Mark E. Michaelian, Henry Shields, Roy D. McGregor, Steven W. Fornaca
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Patent number: 6661018Abstract: A gas jet nozzle (20, 60) for an extreme-ultraviolet light (EUV) source, including a housing (22, 62) having a front (24, 64) and a back (26, 66). The housing (22, 62) is coupleable to a primary gas source (44) and a secondary gas source (46) and is adapted to. expel primary gas (36, 76) and secondary gas (42, 82) from the housing front (24, 64). The housing (22, 62) has a gas-expelling primary channel (39, 70) located centrally within the housing (22, 62) and a gas-expelling secondary channel (34, 74) proximate the primary channel (39, 70). The primary channel (39, 70) may be circular and the secondary channel (34, 74) may be annular, surrounding the primary channel (39, 70). A secondary gas stream (42, 82) expelled from the secondary channel (34, 74) restricts the lateral expansion of a primary gas stream (36, 76) expelled from the primary channel (39, 70), optimizing gas jet properties and reducing heating and erosion of the nozzle (20, 60).Type: GrantFiled: April 25, 2000Date of Patent: December 9, 2003Assignee: Northrop Grumman CorporationInventors: Roy D. McGregor, Charles W. Clendening, Jr.
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Publication number: 20030223546Abstract: A target material delivery system in the form of a nozzle (50) for an EUV radiation source (10). The nozzle (50) includes a target material supply line (66) having an orifice (68) through which droplets (76) of a liquid target material (64) are emitted, where the droplets (76) have a predetermined size, speed and spacing therebetween. The droplets (76) are mixed with a carrier gas (74) in a mixing chamber (54) enclosing the target material chamber (66) and the mixture of the droplets (76) and the carrier gas (74) enter a drift tube (56) from the mixing chamber (54). The droplets (76) are emitted into an accelerator chamber (124) from the drift tube (56) where the speed of the droplets (76) is increased to control the spacing therebetween. A vapor extractor (90) can be mounted to the accelerator chamber (124) or the drift tube (56) to remove the carrier gas (74) and target material vapor, which would otherwise adversely affect the EUV radiation generation.Type: ApplicationFiled: May 28, 2002Publication date: December 4, 2003Inventors: Roy D. McGregor, Robert A. Bunnell, Michael B. Petach, Rocco A. Orsini
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Patent number: 6657213Abstract: A nozzle (46) for a laser-plasma EUV radiation source that provides thermal isolation between the nozzle body (48) and the target material flowing therethrough. A target delivery tube (72) is provided that extends through the nozzle body (48). The delivery tube (72) has an expansion aperture (80) positioned behind an exit collimator (50) of the nozzle body (48). The delivery tube (72) is made of a low thermal conductivity material, such as stainless steel, and is in limited contact with the nozzle body (48) so that heating of the nozzle body (48) from the plasma does not heat the liquid target material being delivered through the delivery tube (72). The expansion aperture (80) has a smaller diameter than the exit collimator (50).Type: GrantFiled: May 3, 2001Date of Patent: December 2, 2003Assignee: Northrop Grumman CorporationInventors: Rocco A. Orsini, Michael B. Petach, Roy D. McGregor
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Publication number: 20020162974Abstract: A nozzle (46) for a laser-plasma EUV radiation source that provides thermal isolation between the nozzle body (48) and the target material flowing therethrough. A target delivery tube (72) is provided that extends through the nozzle body (48). The delivery tube (72) has an expansion aperture (80) positioned behind an exit collimator (50) of the nozzle body (48). The delivery tube (72) is made of a low thermal conductivity material, such as stainless steel, and is in limited contact with the nozzle body (48) so that heating of the nozzle body (48) from the plasma does not heat the liquid target material being delivered through the delivery tube (72). The expansion aperture (80) has a smaller diameter than the exit collimator (50).Type: ApplicationFiled: May 3, 2001Publication date: November 7, 2002Inventors: Rocco A. Orsini, Michael B. Petach, Roy D. McGregor
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Patent number: 6324256Abstract: A laser-plasma EUV radiation source (50) that generates larger liquid droplets (72) for the plasma target material. The EUV source (50) forces a liquid (58), preferably Xenon, through a nozzle (64), instead of forcing a gas through the nozzle. The geometry of the nozzle (64) and the pressure of the liquid (58) through the nozzle (64) atomizes the liquid (58) to form a dense spray (70) of droplets (72). Because the droplets (72) are formed from a liquid, they are larger in size, and are more conducive to generating EUV radiation. A condenser (60) is used to convert gaseous Xenon (54) to the liquid (58) prior to being forced through the nozzle (64).Type: GrantFiled: August 23, 2000Date of Patent: November 27, 2001Assignee: TRW Inc.Inventors: Roy D. McGregor, Michael B. Petach, Rocco A. Orsini