Patent application number | Description | Published |
20090324826 | Film Deposition Apparatus, Film Deposition Method, and Computer Readable Storage Medium - A disclosed film deposition apparatus includes a turntable having in one surface a substrate receiving portion along a turntable rotation direction; a first reaction gas supplying portion for supplying a first reaction gas; a second reaction gas supplying portion for supplying a second reaction gas; a separation area between a first process area where the first reaction gas is supplied and a second process area where the second reaction gas is supplied, the separation area including a separation gas supplying portion for supplying a first separation gas in the separation area, and a ceiling surface opposing the one surface to produce a thin space; a center area having an ejection hole for ejecting a second separation gas along the one surface; and an evacuation opening for evacuating the chamber. | 12-31-2009 |
20090324828 | FILM DEPOSITION APPARATUS, FILM DEPOSITION METHOD, AND COMPUTER READABLE STORAGE MEDIUM - A disclosed film deposition apparatus includes a turntable having in one surface a substrate receiving portion along a turntable rotation direction; a first reaction gas supplying portion for supplying a first reaction gas; a second reaction gas supplying portion for supplying a second reaction gas; a separation area between a first process area where the first reaction gas is supplied and a second process area where the second reaction gas is supplied, the separation area including a separation gas supplying portion for supplying a first separation gas in the separation area, and a ceiling surface opposing the one surface to produce a thin space; a center area having an ejection hole for ejecting a second separation gas along the one surface; and an evacuation opening for evacuating the chamber. | 12-31-2009 |
20110151122 | FILM DEPOSITION APPARATUS, FILM DEPOSITION METHOD, AND COMPUTER READABLE STORAGE MEDIUM - A disclosed film deposition apparatus includes a turntable having in one surface a substrate receiving portion along a turntable rotation direction; a first reaction gas supplying portion for supplying a first reaction gas; a second reaction gas supplying portion for supplying a second reaction gas; a separation area between a first process area where the first reaction gas is supplied and a second process area where the second reaction gas is supplied, the separation area including a separation gas supplying portion for supplying a first separation gas in the separation area, and a ceiling surface opposing the one surface to produce a thin space; a center area having an ejection hole for ejecting a second separation gas along the one surface; and an evacuation opening for evacuating the chamber. | 06-23-2011 |
20130251904 | FILM DEPOSITION METHOD AND COMPUTER READABLE STORAGE MEDIUM - A disclosed film deposition apparatus includes a turntable having in one surface a substrate receiving portion along a turntable rotation direction; a first reaction gas supplying portion for supplying a first reaction gas; a second reaction gas supplying portion for supplying a second reaction gas; a separation area between a first process area where the first reaction gas is supplied and a second process area where the second reaction gas is supplied, the separation area including a separation gas supplying portion for supplying a first separation gas in the separation area, and a ceiling surface opposing the one surface to produce a thin space; a center area having an ejection hole for ejecting a second separation gas along the one surface; and an evacuation opening for evacuating the chamber. | 09-26-2013 |
Patent application number | Description | Published |
20080242109 | METHOD FOR GROWING A THIN OXYNITRIDE FILM ON A SUBSTRATE - A method for growing an oxynitride film on a substrate includes positioning the substrate in a process chamber, heating the process chamber, flowing a wet process gas comprising water vapor and a nitriding gas comprising nitric oxide into the process chamber. The wet process gas and the nitriding gas form a processing ambient that reacts with the substrate such that an oxynitride film grows on the substrate. In yet another embodiment, the method further comprises flowing a diluting gas into the process chamber while flowing the wet process gas to control a growth rate of the oxynitride film. In another embodiment, the method further comprises annealing the substrate and the oxynitride film in an annealing gas. According to embodiments of the method where the substrate is silicon, a silicon oxynitride film forms that exhibits a nitrogen peak concentration of at least approximately 6 atomic % and an interface state density of less than approximately 1.5×10 | 10-02-2008 |
20090035463 | THERMAL PROCESSING SYSTEM AND METHOD FOR FORMING AN OXIDE LAYER ON SUBSTRATES - Thermal processing system and method for forming an oxide layer on substrates. The thermal processing system has a gas injector with first and second fluid lumens confining first and second process gases, such an molecular hydrogen and molecular oxygen, from each other and another fluid lumen that receives the process gases from the first and second fluid lumens. The first and second process gases combine and react in this fluid lumen to form a reaction product. The reaction product is injected from this fluid lumen into a process chamber of the thermal processing system, where substrates are exposed to the reaction product resulting in formation of an oxide layer. | 02-05-2009 |
20090088000 | METHOD FOR GROWING AN OXYNITRIDE FILM ON A SUBSTRATE - A method for growing an oxynitride film on a substrate includes positioning the substrate in a process chamber, heating the process chamber, flowing a first wet process gas comprising water vapor into the process chamber, and reacting the substrate with the first wet process gas to grow an oxide film on the substrate. The method further includes flowing a second wet process gas comprising water vapor and a nitriding gas comprising nitric oxide into the process chamber, and reacting the oxide film and the substrate with the second wet process gas to grow an oxynitride film. In another embodiment, the method further comprises annealing the substrate containing the oxynitride film in an annealing gas. According to one embodiment of the method where the substrate is silicon, a silicon oxynitride film can be formed that exhibits a nitrogen peak concentration of approximately 3 atomic % or greater. | 04-02-2009 |
20090246971 | IN-SITU HYBRID DEPOSITION OF HIGH DIELECTRIC CONSTANT FILMS USING ATOMIC LAYER DEPOSITION AND CHEMICAL VAPOR DEPOSITION - An in-situ hybrid film deposition method for forming a high-k dielectric film on a plurality of substrates in a batch processing system. The method includes loading the plurality of substrates into a process chamber of the batch processing system, depositing by atomic layer deposition (ALD) a first portion of a high-k dielectric film on the plurality of substrates, after depositing the first portion, and without removing the plurality of substrates from the process chamber, depositing by chemical vapor deposition (CVD) a second portion of the high-k dielectric film on the first portion, and removing the plurality of substrates from the process chamber. The method can further include alternatingly repeating the deposition of the first and second portions until the high-k dielectric film has a desired thickness. The method can still further include pre-treating the substrates and post-treating the high-k dielectric film in-situ prior to the removing. | 10-01-2009 |
20110241085 | DUAL SIDEWALL SPACER FOR SEAM PROTECTION OF A PATTERNED STRUCTURE - A semiconducting device with a dual sidewall spacer and method of forming are provided. The method includes: depositing a first spacer layer over a patterned structure, the first spacer layer having a seam propagating through a thickness of the first spacer layer near an interface region of a surface of the substrate and a sidewall of the patterned structure, etching the first spacer layer to form a residual spacer at the interface region, where the residual spacer coats less than the entirety of the sidewall of the patterned structure, depositing a second spacer layer on the residual spacer and on the sidewall of the patterned structure not coated by the residual spacer, the second spacer layer being seam-free on the seam of the residual spacer, and etching the second spacer layer to form a second spacer coating the residual spacer and coating the sidewall of the patterned structure not coated by the residual spacer. | 10-06-2011 |
20110241128 | MULTILAYER SIDEWALL SPACER FOR SEAM PROTECTION OF A PATTERNED STRUCTURE - A semiconducting device with a multilayer sidewall spacer and method of forming are described. In one embodiment, the method includes providing a substrate containing a patterned structure on a surface of the substrate and depositing a first spacer layer over the patterned structure at a first substrate temperature, where the first spacer layer contains a first material. The method further includes depositing a second spacer layer over the patterned substrate at a second substrate temperature that is different from the first substrate temperature, where the first and second materials contain the same chemical elements, and the depositing steps are performed in any order. The first and second spacer layers are then etched to form the multilayer sidewall spacer on the patterned structure. | 10-06-2011 |
20120003825 | METHOD OF FORMING STRAINED EPITAXIAL CARBON-DOPED SILICON FILMS - A method for forming strained epitaxial carbon-doped silicon (Si) films, for example as raised source and drain regions for electronic devices. The method includes providing a structure having an epitaxial Si surface and a patterned film, non-selectively depositing a carbon-doped Si film onto the structure, the carbon-doped Si film containing an epitaxial carbon-doped Si film deposited onto the epitaxial Si surface and a non-epitaxial carbon-doped Si film deposited onto the patterned film, and non-selectively depositing a Si film on the carbon-doped Si film, the Si film containing an epitaxial Si film deposited onto the epitaxial carbon-doped Si film and a non-epitaxial Si film deposited onto the non-epitaxial carbon-doped Si film. The method further includes dry etching away the non-epitaxial Si film, the non-epitaxial carbon-doped Si film, and less than the entire epitaxial Si film to form a strained epitaxial carbon-doped Si film on the epitaxial Si surface. | 01-05-2012 |