Patents by Inventor Hyung-sang Park
Hyung-sang Park 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).
-
Publication number: 20130147053Abstract: A semiconductor device includes a first carrier having a first resin disposed over the first carrier. A fabric is disposed over the first resin. A second resin is formed over the first resin and around the fabric to form an asymmetrical pre-impregnated (PPG) substrate. The first carrier is removed. A second carrier is provided and a first conductive layer is formed over the second carrier. A portion of the first conductive layer is removed. The first conductive layer is transferred from the second carrier to the first resin. The first conductive layer is oriented asymmetrically such that the first conductive layer is offset with respect to the fabric to minimize warpage. The second carrier is removed. A via is formed through the second resin and fabric to expose the first conductive layer. A second conductive layer formed in the via over the first conductive layer.Type: ApplicationFiled: December 8, 2011Publication date: June 13, 2013Applicant: STATS CHIPPAC, LTD.Inventors: Hyung Sang Park, Sung Soo Kim, SungWon Cho
-
Patent number: 8273408Abstract: Cyclical methods of depositing a ruthenium layer on a substrate are provided. In one process, initial or incubation cycles include supplying alternately and/or simultaneously a ruthenium precursor and an oxygen-source gas to deposit ruthenium oxide on the substrate. The ruthenium oxide deposited on the substrate is reduced to ruthenium, thereby forming a ruthenium layer. The oxygen-source gas may be oxygen gas (O2). The ruthenium oxide may be reduced by supplying a reducing agent, such as ammonia (NH3) gas. The methods provide a ruthenium layer having good adherence to an underlying high dielectric layer while providing good step coverage over structures on the substrate. After nucleation, subsequent deposition cycles can be altered to optimize speed and/or conformality rather than adherence.Type: GrantFiled: October 14, 2008Date of Patent: September 25, 2012Assignee: ASM Genitech Korea Ltd.Inventors: Jong Su Kim, Hyung Sang Park
-
Patent number: 8252691Abstract: Semiconductor patterns are formed by performing trimming simultaneously with the process of depositing the spacer oxide. Alternatively, a first part of the trimming is performed in-situ, immediately before the spacer oxide deposition process in the same chamber in which the spacer oxide deposition is performed whereas a second part of the trimming is performed simultaneously with the process of depositing the spacer oxide. Thus, semiconductor patterns are formed reducing PR footing during PR trimming with direct plasma exposure.Type: GrantFiled: April 13, 2011Date of Patent: August 28, 2012Assignee: ASM Genitech Korea Ltd.Inventors: Julien Beynet, Hyung Sang Park, Naoki Inoue
-
Patent number: 8242029Abstract: An atomic layer deposition-deposited silicon dioxide/metal oxide-nanolaminate, comprising at least one layer of silicon dioxide and at least one layer of a metal oxide, and having a wet etch rate in an etchant, said wet etch rate being either greater or smaller than both a wet etch rate of a film of silicon dioxide and a wet etch rate of a film of said metal oxide in said etchant. Also provided is a method for manufacturing the same.Type: GrantFiled: November 23, 2009Date of Patent: August 14, 2012Assignee: ASM International N.V.Inventors: Peter Zagwijn, Hyung-Sang Park, Stijn De Vusser
-
Patent number: 8215264Abstract: The present invention relates to an ALD apparatus, and particularly relates to an ALD apparatus that is suitable for rapidly depositing a thin film on a substrate having an actual area that is larger than a planar substrate. In the reaction chamber of the ALD apparatus according to an exemplary embodiment of the present invention, more gas is supplied to a portion where more gas is required by having differences in the space for gas to flow rather than supplying the gas in a constant flux and a constant flow velocity such that the time required for supplying reactant gases and waste of reactant gases may be minimized to increase productivity of the ALD apparatus. The ceiling of the reaction space is shaped to provide a nonuniform gap over the substrate.Type: GrantFiled: June 29, 2011Date of Patent: July 10, 2012Assignee: ASM Genitech Korea Ltd.Inventors: Kyung Il Hong, Dae Youn Kim, Hyung-Sang Park, Sang Jin Jeong, Wonyong Koh, Herbert Terhorst
-
Publication number: 20120114856Abstract: A deposition apparatus configured to form a thin film on a substrate includes: a reactor wall; a substrate support positioned under the reactor wall; and a showerhead plate positioned above the substrate support. The showerhead plate defines a reaction space together with the substrate support. The apparatus also includes one or more gas conduits configured to open to a periphery of the reaction space at least while an inert gas is supplied therethrough. The one or more gas conduits are configured to supply the inert gas inwardly toward the periphery of the substrate support around the reaction space. This configuration prevents reactant gases from flowing between a substrate and the substrate support during a deposition process, thereby preventing deposition of an undesired thin film and impurity particles on the back side of the substrate.Type: ApplicationFiled: January 9, 2012Publication date: May 10, 2012Applicant: ASM GENITECH KOREA LTD.Inventors: Hyung Sang Park, Seung Woo Choi, Jong Su Kim, Dong Rak Jung, Jeong Ho Lee, Chun Soo Lee
-
Publication number: 20120043672Abstract: A semiconductor device has a first substrate and first conductive pillars formed over the first substrate. Second conductive pillars are formed over the first substrate alternating with the first conductive pillars. The second conductive pillars are vertically offset with respect to the first conductive pillars. First BOT interconnect sites are formed over a second substrate. Second BOT interconnect sites are formed over the second substrate alternating with the first interconnect sites. The second interconnect sites are vertically offset with respect to the first interconnect sites. The first substrate is mounted to the second substrate such that the first conductive pillars are aligned with and electrically connected to the first interconnect sites and the second conductive pillars are aligned with and electrically connected to the second interconnect sites. An underfill material is deposited between the first and second substrates. The first substrate can be a flipchip type semiconductor device.Type: ApplicationFiled: August 17, 2010Publication date: February 23, 2012Applicant: STATS CHIPPAC, LTD.Inventors: SungWon Cho, KiYoun Jang, YongHee Kang, Hyung Sang Park
-
Patent number: 8092606Abstract: A deposition apparatus configured to form a thin film on a substrate includes: a reactor wall; a substrate support positioned under the reactor wall; and a showerhead plate positioned above the substrate support. The showerhead plate defines a reaction space together with the substrate support. The apparatus also includes one or more gas conduits configured to open to a periphery of the reaction space at least while an inert gas is supplied therethrough. The one or more gas conduits are configured to supply the inert gas inwardly toward the periphery of the substrate support around the reaction space. This configuration prevents reactant gases from flowing between a substrate and the substrate support during a deposition process, thereby preventing deposition of an undesired thin film and impurity particles on the back side of the substrate.Type: GrantFiled: December 12, 2008Date of Patent: January 10, 2012Assignee: ASM Genitech Korea Ltd.Inventors: Hyung Sang Park, Seung Woo Choi, Jong Su Kim, Dong Rak Jung, Jeong Ho Lee, Chun Soo Lee
-
Publication number: 20110308460Abstract: The present invention relates to an ALD apparatus, and particularly relates to an ALD apparatus that is suitable for rapidly depositing a thin film on a substrate having an actual area that is larger than a planar substrate. In the reaction chamber of the ALD apparatus according to an exemplary embodiment of the present invention, more gas is supplied to a portion where more gas is required by having differences in the space for gas to flow rather than supplying the gas in a constant flux and a constant flow velocity such that the time required for supplying reactant gases and waste of reactant gases may be minimized to increase productivity of the ALD apparatus. The ceiling of the reaction space is shaped to provide a nonuniform gap over the substrate.Type: ApplicationFiled: June 29, 2011Publication date: December 22, 2011Applicant: ASM GENITECH KOREA LTD.Inventors: Kyung Il Hong, Dae Youn Kim, Hyung-Sang Park, Sang Jin Jeong, Wonyong Koh, Herbert Terhorst
-
Patent number: 8076242Abstract: A method for forming an amorphous silicon thin film is disclosed. In some embodiments, a method includes loading a substrate into a reaction chamber; and conducting a plurality of deposition cycles on the substrate. Each of at least two of the cycles includes: supplying a silicon precursor to the reaction chamber during a first time period; applying radio frequency power to the reaction chamber at least partly during the first time period; stopping supplying of the silicon precursor and applying of the radio frequency power during a second time period between the first time period and an immediately subsequent deposition cycle; and supplying hydrogen plasma to the reaction chamber during a third time period between the second time period and the immediately subsequent deposition cycle. The method allows formation of an amorphous silicon film having an excellent step-coverage and a low roughness at a relatively low deposition temperature.Type: GrantFiled: April 30, 2009Date of Patent: December 13, 2011Assignee: ASM Genitech Korea Ltd.Inventors: Jong Su Kim, Hyung Sang Park, Yong Min Yoo, Hak Yong Kwon, Tae Ho Yoon
-
Publication number: 20110256727Abstract: Semiconductor patterns are formed by performing trimming simultaneously with the process of depositing the spacer oxide. Alternatively, a first part of the trimming is performed in-situ, immediately before the spacer oxide deposition process in the same chamber in which the spacer oxide deposition is performed whereas a second part of the trimming is performed simultaneously with the process of depositing the spacer oxide. Thus, semiconductor patterns are formed reducing PR footing during PR trimming with direct plasma exposure.Type: ApplicationFiled: April 13, 2011Publication date: October 20, 2011Applicant: ASM GENITECH KOREA LTD.Inventors: Julien Beynet, Hyung Sang Park, Naoki Inoue
-
Patent number: 7976898Abstract: The present invention relates to an ALD apparatus, and particularly relates to an ALD apparatus that is suitable for rapidly depositing a thin film on a substrate having an actual area that is larger than a planar substrate. In the reaction chamber of the ALD apparatus according to an exemplary embodiment of the present invention, more gas is supplied to a portion where more gas is required by having differences in the space for gas to flow rather than supplying the gas in a constant flux and a constant flow velocity such that the time required for supplying reactant gases and waste of reactant gases may be minimized to increase productivity of the ALD apparatus. The ceiling of the reaction space is shaped to provide a nonuniform gap over the substrate.Type: GrantFiled: September 18, 2007Date of Patent: July 12, 2011Assignee: ASM Genitech Korea Ltd.Inventors: Kyung Il Hong, Dae Youn Kim, Hyung-Sang Park, Sang Jin Jeong, Wonyong Koh, Herbert Terhorst
-
Publication number: 20110121430Abstract: An atomic layer deposition-deposited silicon dioxide/metal oxide-nanolaminate, comprising at least one layer of silicon dioxide and at least one layer of a metal oxide, and having a wet etch rate in an etchant, said wet etch rate being either greater or smaller than both a wet etch rate of a film of silicon dioxide and a wet etch rate of a film of said metal oxide in said etchant. Also provided is a method for manufacturing the same.Type: ApplicationFiled: November 23, 2009Publication date: May 26, 2011Inventors: Peter Zagwijn, Hyung-Sang Park, Stijn De Vusser
-
Publication number: 20110020545Abstract: A deposition apparatus according to an exemplary embodiment of the present invention is a lateral-flow deposition apparatus in which in which a process gas flows between a surface where a substrate is disposed and the opposite surface, substantially in parallel with the substrate. The lateral-flow deposition apparatus includes: a substrate support that moves up/down and rotates the substrate while supporting the substrate; a reactor cover that defines a reaction chamber by contacting the substrate support; and a substrate support lifter and a substrate support rotator that move the substrate support.Type: ApplicationFiled: July 21, 2010Publication date: January 27, 2011Applicant: ASM GENITECH KOREA LTD.Inventors: Ki Jong Kim, Yong Min Yoo, Jung Soo Kim, Hyung Sang Park, Seung Woo Choi, Jeong Ho Lee, Dong Rak Jung
-
Patent number: 7694928Abstract: A cup holder includes: a support housing; an elevator housing, movable within the support housing; a cup bearing tray, movable within the elevator housing; and an elevator unit that moves the elevator housing and the cup bearing tray in opposite directions. The elevator unit includes: a main gear that is linked with the cup bearing tray and is pivotably installed on the support housing, a rack gear that is linked with the elevator housing, and a driven gear that is engaged between the main gear and the rack gear.Type: GrantFiled: November 19, 2007Date of Patent: April 13, 2010Assignee: Hyundai Motor CompanyInventors: Kwang Gi Lee, Hyung Sang Park
-
Publication number: 20090278224Abstract: A method for forming an amorphous silicon thin film is disclosed. In some embodiments, a method includes loading a substrate into a reaction chamber; and conducting a plurality of deposition cycles on the substrate. Each of at least two of the cycles includes: supplying a silicon precursor to the reaction chamber during a first time period; applying radio frequency power to the reaction chamber at least partly during the first time period; stopping supplying of the silicon precursor and applying of the radio frequency power during a second time period between the first time period and an immediately subsequent deposition cycle; and supplying hydrogen plasma to the reaction chamber during a third time period between the second time period and the immediately subsequent deposition cycle. The method allows formation of an amorphous silicon film having an excellent step-coverage and a low roughness at a relatively low deposition temperature.Type: ApplicationFiled: April 30, 2009Publication date: November 12, 2009Applicant: ASM GENITECH KOREA LTD.Inventors: Jong Su Kim, Hyung Sang Park, Yong Min Yoo, Hak Yong Kwon, Tae Ho Yoon
-
Publication number: 20090163024Abstract: A method of depositing includes: loading a substrate into a reactor; and conducting a plurality of atomic layer deposition cycles on the substrate in the reactor. At least one of the cycles includes steps of: supplying a ruthenium precursor to the reactor; supplying a purge gas to the reactor; and supplying non-plasma ammonia gas to the reactor after supplying the ruthenium precursor. The method allows formation of a ruthenium layer having an excellent step-coverage at a relatively low deposition temperature at a relatively high deposition rate. In situ isothermal deposition of barrier materials, such as TaN at 200-300° C., is also facilitated.Type: ApplicationFiled: December 17, 2008Publication date: June 25, 2009Applicant: ASM GENITECH KOREA LTD.Inventors: Jeon Ho Kim, Hyung Sang Park, Seung Woo Choi, Dong Rak Jung, Chun Soo Lee
-
Publication number: 20090155606Abstract: Cyclical methods of depositing a silicon nitride film on a substrate are provided. In one embodiment, a method includes supplying a chlorosilane to a reactor in which a substrate is processed; supplying a purge gas to the reactor; and providing ammonia plasma to the reactor. The method allows a silicon nitride film to be formed at a low process temperature and a high deposition rate. The resulting silicon nitride film has a relatively few impurities and a relatively high quality. In addition, a silicon nitride film having good step coverage over features having high aspect ratios and a thin and uniform thickness can be formed.Type: ApplicationFiled: December 1, 2008Publication date: June 18, 2009Applicant: ASM GENITECH KOREA LTD.Inventors: Tae Ho Yoon, Hyung Sang Park, Hak Yong Kwon, Young Jae Kim
-
Publication number: 20090156015Abstract: A deposition apparatus configured to form a thin film on a substrate includes: a reactor wall; a substrate support positioned under the reactor wall; and a showerhead plate positioned above the substrate support. The showerhead plate defines a reaction space together with the substrate support. The apparatus also includes one or more gas conduits configured to open to a periphery of the reaction space at least while an inert gas is supplied therethrough. The one or more gas conduits are configured to supply the inert gas inwardly toward the periphery of the substrate support around the reaction space. This configuration prevents reactant gases from flowing between a substrate and the substrate support during a deposition process, thereby preventing deposition of an undesired thin film and impurity particles on the back side of the substrate.Type: ApplicationFiled: December 12, 2008Publication date: June 18, 2009Applicant: ASM GENITECH KOREA LTD.Inventors: Hyung Sang Park, Seung Woo Choi, Jong Su Kim, Dong Rak Jung, Jeong Ho Lee, Chun Soo Lee
-
Patent number: 7541284Abstract: A ruthenium film deposition method is disclosed. In one embodiment of the method, a first ruthenium film is deposited by using a PEALD process until a substrate is substantially entirely covered with the first ruthenium film. Then, a second ruthenium film is deposited on the first ruthenium film by using a thermal ALD process having a higher deposition speed than that of the PEALD process. In the method, a ruthenium metal film having a high density is formed in a short time by combining a PEALD process of depositing a ruthenium film at a low deposition speed and a deposition process of depositing a ruthenium film at a higher deposition speed. Accordingly, it is possible to form a ruthenium film having high density, a smooth surface, good adhesiveness, and a short incubation period.Type: GrantFiled: February 14, 2007Date of Patent: June 2, 2009Assignee: ASM Genitech Korea Ltd.Inventor: Hyung-Sang Park