Patent application number | Description | Published |
20090097017 | OPTICAL INSPECTION METHODS - Inspection methods. A method includes adhering an optical blocking layer directly onto and in direct mechanical contact with a semiconductor process wafer, the blocking layer being substantially opaque to a range of wavelengths of light; applying at least one layer over the blocking layer; and inspecting optically at least one wavelength at least one inspection area, the blocking layer extending substantially throughout the inspection area. An inspection method including adhering an optical absorbing layer to a semiconductor process wafer, where the absorbing layer is configured to substantially absorb a range of wavelengths of light; applying at least one layer over the absorbing layer; and inspecting optically at least one wavelength at least one inspection area of the process wafer. A manufacturing method including ascertaining if a defect is present within a photoresist layer, and changing a semiconductor manufacturing process to prevent the defect, if the defect is present. | 04-16-2009 |
20090117360 | SELF-ASSEMBLED MATERIAL PATTERN TRANSFER CONTRAST ENHANCEMENT - A non-photosensitive polymeric resist containing at least two immiscible polymeric block components is deposited on the planar surface. The non-photosensitive polymeric resist is annealed to allow phase separation of immiscible components and developed to remove at least one of the at least two polymeric block components. Nanoscale features, i.e., features of nanometer scale, including at least one recessed region having a nanoscale dimension is formed in the polymeric resist. The top surface of the polymeric resist is modified for enhanced etch resistance by an exposure to an energetic beam, which allows the top surface of the patterned polymeric resist to become more resistant to etching processes and chemistries. The enhanced ratio of etch resistance between the two types of surfaces provides improved image contrast and fidelity between areas having the top surface and the at least one recessed region. | 05-07-2009 |
20090176350 | INTEGRATION OF ION GETTERING MATERIAL IN DIELECTRIC - A method embodiment deposits a first dielectric layer over a transistor and then implants a gettering agent into the first dielectric layer. After this first dielectric layer is formed, the method forms a second (thicker) dielectric layer over the first dielectric layer. After this, the standard contacts are formed through the insulating layer to the source, drain, gate, etc. of the transistor. Additionally, reactive ion etching, chemical mechanical processing, and other back-end-of-line processing are performed. The back-end-of-line processes can introduce mobile ions into the dielectric over a transistor; however, the gettering agent traps the mobile ions and prevents the mobile ions from contaminating the transistor. | 07-09-2009 |
20100112730 | OPTICAL INSPECTION METHODS - Inspection methods. A method includes adhering an optical blocking layer directly onto and in direct mechanical contact with a semiconductor process wafer, the blocking layer being substantially opaque to a range of wavelengths of light; applying at least one layer over the blocking layer; and inspecting optically at least one wavelength at least one inspection area, the blocking layer extending substantially throughout the inspection area. An inspection method including adhering an optical absorbing layer to a semiconductor process wafer, where the absorbing layer is configured to substantially absorb a range of wavelengths of light; applying at least one layer over the absorbing layer; and inspecting optically at least one wavelength at least one inspection area of the process wafer. A manufacturing method including ascertaining if a defect is present within a photoresist layer, and changing a semiconductor manufacturing process to prevent the defect, if the defect is present. | 05-06-2010 |
20120153474 | INTEGRATED CIRCUIT SYSTEM WITH REDUCED POLYSILICON RESIDUE AND METHOD OF MANUFACTURE THEREOF - A method of manufacturing an integrated circuit system includes: providing a substrate; forming a polysilicon layer over the substrate; forming an anti-reflective coating layer over the polysilicon layer; etching an anti-reflective coating pattern into the anti-reflective coating layer leaving an anti-reflective coating residue over the polysilicon layer; and etching the anti-reflective coating residue with an etchant gas mixture comprising hydrogen bromide, chlorine, and oxygen to remove the anti-reflective coating residue for mitigating the formation of a polysilicon protrusion. | 06-21-2012 |
20120168957 | METHOD TO REDUCE DEPTH DELTA BETWEEN DENSE AND WIDE FEATURES IN DUAL DAMASCENE STRUCTURES - A method of forming a device is disclosed. The method includes providing a substrate prepared with a dielectric layer having first and second regions. The first region comprises wide features and the second region comprises narrow features. A depth delta exists between bottoms of the wide and narrow features. A non-conformal layer is formed on the substrate and it lines the wide and narrow trenches in the first and second regions. The non-conformal layer is removed. Removing the non-conformal layer reduces the depth delta between the bottoms of the wide and narrow features in the first and second region. | 07-05-2012 |
20120178241 | CONDUCTIVE METAL AND DIFFUSION BARRIER SEED COMPOSITIONS, AND METHODS OF USE IN SEMICONDUCTOR AND INTERLEVEL DIELECTRIC SUBSTRATES - A metal seed composition useful in seeding a metal diffusion barrier or conductive metal layer on a semiconductor or dielectric substrate, the composition comprising: a nanoscopic metal component that includes a metal useful as a metal diffusion barrier or conductive metal; an adhesive component for attaching said nanoscopic metal component on said semiconductor or dielectric substrate; and a linker component that links said nanoscopic metal component with said adhesive component. Semiconductor and dielectric substrates coated with the seed compositions, as well as methods for depositing the seed compositions, are also described. | 07-12-2012 |
20120256299 | ARC RESIDUE-FREE ETCHING - Antireflective residues during pattern transfer and consequential short circuiting are eliminated by employing an underlying sacrificial layer to ensure complete removal of the antireflective layer. Embodiments include forming a hard mask layer over a conductive layer, e.g., a silicon substrate, forming the sacrificial layer over the hard mask layer, forming an optical dispersive layer over the sacrificial layer, forming a silicon anti-reflective coating layer over the optical dispersive layer, forming a photoresist layer over the silicon anti-reflective coating layer, where the photoresist layer defines a pattern, etching to transfer the pattern to the hard mask layer, and stripping at least the optical dispersive layer and the sacrificial layer. | 10-11-2012 |
20130295773 | Method for Simultaneously Forming Features of Different Depths in a Semiconductor Substrate - Embodiments of the invention may include first providing a stack of layers including a semiconductor substrate, a buried oxide layer on the semiconductor substrate, a semiconductor-on-insulator layer on the buried-oxide layer, a nitride layer on the semiconductor-on-insulator layer, and a silicon oxide layer on the nitride layer. A first opening and second opening with a smaller cross-sectional area than the first opening are then formed in the silicon oxide layer, the nitride layer, the semiconductor-on-insulator layer, and the buried-oxide layer. The first opening and the second opening are then etched with a first etching gas. The first opening and the second opening are then etched with a second etching gas, which includes the first etching gas and a halogenated silicon compound, for example, silicon tetrafluoride or silicon tetrachloride. In one embodiment, the first etching gas includes hydrogen bromide, nitrogen trifluoride, and oxygen. | 11-07-2013 |
20150054179 | ARC RESIDUE-FREE ETCHING - Antireflective residues during pattern transfer and consequential short circuiting are eliminated by employing an underlying sacrificial layer to ensure complete removal of the antireflective layer. Embodiments include forming a hard mask layer over a conductive layer, e.g., a silicon substrate, forming the sacrificial layer over the hard mask layer, forming an optical dispersive layer over the sacrificial layer, forming a silicon anti-reflective coating layer over the optical dispersive layer, forming a photoresist layer over the silicon anti-reflective coating layer, where the photoresist layer defines a pattern, etching to transfer the pattern to the hard mask layer, and stripping at least the optical dispersive layer and the sacrificial layer. | 02-26-2015 |