Patent application number | Description | Published |
20100095252 | CHANNEL LENGTH SCALING FOR FOOTPRINT COMPATIBLE DIGITAL LIBRARY CELL DESIGN - Effective GDS-based channel length scaling. A library cell is designed, and then the width of the polys is increased, and the polys and contacts are shifted in order to maintain poly-to-poly and contact-to-poly spacing. The method can be used in association with a 45 nm digital library cell. Specifically, a library cell having 40 nm polys is designed, and then the width of each of the polys is increased by 5 nm to 45 nm, and the polys and contacts are shifted in order to maintain poly-to-poly and contact-to-poly spacing. The poly lines and contacts can be shifted by starting at the center and going out radially, or by beginning at the perimeter and moving radially inward. The method can be used with any library cell design which is entirely GDS based, including, for example, 32 nm library cell design. | 04-15-2010 |
20110111330 | METHOD OF CREATING PHOTOLITHOGRAPHIC MASKS FOR SEMICONDUCTOR DEVICE FEATURES WITH REDUCED DESIGN RULE VIOLATIONS - A method of creating photolithographic masks for semiconductor device features with reduced design rule violations is provided. The method begins by providing preliminary data that represents an overall mask pattern. The preliminary data is processed to decompose the overall mask pattern into a plurality of component mask patterns. Next, a design rule check is performed on the plurality of component mask patterns to identify tip-to-tip and tip-to-line violations in the plurality of component mask patterns. The method continues by modifying at least one of the plurality of component mask patterns in accordance with the identified violations to obtain a modified set of component mask patterns, wherein each mask pattern in the modified set of component mask patterns is void of tip-to-tip and tip-to-line violations. Photolithographic masks are then created for the modified set of component mask patterns. | 05-12-2011 |
20110111348 | SEMICONDUCTOR DEVICE FABRICATION USING A MULTIPLE EXPOSURE AND BLOCK MASK APPROACH TO REDUCE DESIGN RULE VIOLATIONS - A method of fabricating a semiconductor device begins by forming a layer of hard mask material on a substrate comprising a layer of semiconductor material and a layer of insulating material overlying the layer of semiconductor material, such that the layer of hard mask material overlies the layer of insulating material. A multiple exposure photolithography procedure is performed to create a combined pattern of photoresist features overlying the layer of hard mask material, and a recess line pattern is in the hard mask material, using the combined pattern of photoresist features. The method continues by covering designated sections of the recess line pattern with a blocking pattern of photoresist features, and forming a pattern of trenches in the insulating material, where the pattern of trenches is defined by the blocking pattern of photoresist features and the hard mask material. Thereafter, an electrically conductive material is deposited in the trenches, resulting in conductive lines for the semiconductor device. | 05-12-2011 |
Patent application number | Description | Published |
20090051006 | N CELL HEIGHT DECOUPLING CIRCUIT - A decoupling circuit disposed between a first rail and a second rail, where a third power rail is disposed between the first and second rails. A resistor having a first electrode and a second electrode is disposed between the first and second rails. Two capacitors are disposed between the first and second rails. The resistor is connected to the third rail and the two capacitors. In this manner, the two capacitors are connected in series with respect to the resistor, and in parallel with respect to one another. A first of the two capacitors is connected to the first rail, and a second of the two capacitors is connected to the second rail. At least one of the resistor and the two capacitors is disposed at least in part beneath the third rail. | 02-26-2009 |
20100197096 | METHODS FOR FABRICATING FINFET STRUCTURES HAVING DIFFERENT CHANNEL LENGTHS - Methods for fabricating FinFET structures having gate structures of different gate widths are provided. The methods include the formation of sidewall spacers of different thicknesses to define gate structures of the FinFET structures with different gate widths. The width of a sidewall spacer is defined by the height of the structure about which the sidewall spacer is formed, the thickness of the sidewall spacer material layer from which the spacer is formed, and the etch parameters used to etch the sidewall spacer material layer. By forming structures of varying height, forming the sidewall spacer material layer of varying thickness, or a combination of these, sidewall spacers of varying width can be fabricated and subsequently used as an etch mask so that gate structures of varying widths can be formed simultaneously. | 08-05-2010 |
20100248481 | CAD FLOW FOR 15NM/22NM MULTIPLE FINE GRAINED WIMPY GATE LENGTHS IN SIT GATE FLOW - Methods are described for forming an integrated circuit having multiple devices, such as transistors, with respective element lengths. The methods include a new CAD flow for producing masks used for exposing sidewall spacers which are to be etched to a smaller base width than other sidewall spacers and which in turn are used as an etch mask to form gate structures with smaller element lengths than those formed from the other sidewall spacers. Embodiments include generating a schematic of an integrated circuit and a corresponding netlist, establishing design rules for the integrated circuit, generating a computer aided design layout for the integrated circuit, plural transistors of the integrated circuit respectively having different gate lengths, checking the integrated circuit layout and netlist for compliance with the established design rules and for correspondence with the generated schematic, and generating a mask with different openings that correspond to the integrated circuit layout, in response to a satisfactory outcome of the checking step. | 09-30-2010 |
20100301482 | SRAM BIT CELL WITH SELF-ALIGNED BIDIRECTIONAL LOCAL INTERCONNECTS - Improved SRAMs are formed with significantly reduced local interconnect to gate shorts, by a technique providing bidirectional, self-aligned local interconnects, employing a gate hard mask over portions of the gates not connected to the local interconnects. Embodiments include forming a gate hard mask over gates, forming bidirectional trenches overlying portions of the gate electrodes and active silicon regions, etching the hard mask layer to expose regions of the gate electrodes that are to connect to local interconnects, and filling the trenches with conductive material to form self-aligned local interconnects. | 12-02-2010 |
20110014791 | METHODS FOR FABRICATING FINFET STRUCTURES HAVING DIFFERENT CHANNEL LENGTHS - Methods for fabricating FinFET structures having gate structures of different gate widths are provided. The methods include the formation of sidewall spacers of different thicknesses to define gate structures of the FinFET structures with different gate widths. The width of a sidewall spacer is defined by the height of the structure about which the sidewall spacer is formed, the thickness of the sidewall spacer material layer from which the spacer is formed, and the etch parameters used to etch the sidewall spacer material layer. By forming structures of varying height, forming the sidewall spacer material layer of varying thickness, or a combination of these, sidewall spacers of varying width can be fabricated and subsequently used as an etch mask so that gate structures of varying widths can be formed simultaneously. | 01-20-2011 |
20120025316 | Process for Forming FINS for a FinFET Device - An integrated fin-based field effect transistor (FinFET) and method of fabricating such devices on a bulk wafer with EPI-defined fin heights over shallow trench isolation (STI) regions. The FinFET channels overlie the STI regions within the semiconductor bulk, while the fins extend beyond the STI regions into the source and drain regions which are implanted within the semiconductor bulk. With bulk source and drain regions, reduced external FinFET resistance is provided, and with the fins extending into the bulk source and drain regions, improved thermal properties is provided over conventional silicon on insulator (SOI) devices. | 02-02-2012 |
20120037996 | SRAM BIT CELL WITH SELF-ALIGNED BIDIRECTIONAL LOCAL INTERCONNECTS - Improved SRAMs are formed with significantly reduced local interconnect to gate shorts, by a technique providing bidirectional, self-aligned local interconnects, employing a gate hard mask over portions of the gates not connected to the local interconnects. Embodiments include forming a gate hard mask over gates, forming bidirectional trenches overlying portions of the gate electrodes and active silicon regions, etching the hard mask layer to expose regions of the gate electrodes that are to connect to local interconnects, and filling the trenches with conductive material to form self-aligned local interconnects. | 02-16-2012 |
20120313148 | SELF-ALIGNED TRENCH CONTACT AND LOCAL INTERCONNECT WITH REPLACEMENT GATE PROCESS - A semiconductor device fabrication process includes forming insulating mandrels over one or more replacement metal gates on a semiconductor substrate. The mandrels include a first insulating material. Each mandrel has approximately the same width as its underlying gate with each mandrel being at least as wide as its underlying gate. Mandrel spacers are formed around each insulating mandrel. The mandrel spacers include the first insulating material. Each mandrel spacer has a profile that slopes from being wider at the bottom to narrower at the top. A second insulating layer of the second insulating material is formed over the transistor. Trenches to the sources and drains of the gates are formed by removing the second insulating material from portions of the transistor between the mandrels. Trench contacts to the sources and drains of the gates are formed by depositing conductive material in the first trenches. | 12-13-2012 |
20130119474 | TRENCH SILICIDE AND GATE OPEN WITH LOCAL INTERCONNECT WITH REPLACEMENT GATE PROCESS - A semiconductor device fabrication process includes forming insulating mandrels over replacement metal gates on a semiconductor substrate with first gates having sources and drains and at least one second gate being isolated from the first gates. Mandrel spacers are formed around each insulating mandrel. The mandrels and mandrel spacers include the first insulating material. A second insulating layer of the second insulating material is formed over the transistor. One or more first trenches are formed to the sources and drains of the first gates by removing the second insulating material between the insulating mandrels. A second trench is formed to the second gate by removing portions of the first and second insulating materials above the second gate. The first trenches and the second trench are filled with conductive material to form first contacts to the sources and drains of the first gates and a second contact to the second gate. | 05-16-2013 |
20140145342 | METAL DENSITY DISTRIBUTION FOR DOUBLE PATTERN LITHOGRAPHY - Methods, a computer readable medium, and an apparatus are provided. A method includes and the computer readable medium is configured for decomposing an overall pattern into a first mask pattern that includes a power rail base pattern and into a second mask pattern, and generating on the second mask pattern a power rail insert pattern that is at least partially aligned with the power rail base pattern of the first mask pattern. The apparatus is produced by photolithography using photolithographic masks generated by the method. | 05-29-2014 |
20140197494 | TRENCH SILICIDE AND GATE OPEN WITH LOCAL INTERCONNECT WITH REPLACEMENT GATE PROCESS - A semiconductor device fabrication process includes forming insulating mandrels over replacement metal gates on a semiconductor substrate with first gates having sources and drains and at least one second gate being isolated from the first gates. Mandrel spacers are formed around each insulating mandrel. The mandrels and mandrel spacers include the first insulating material. A second insulating layer of the second insulating material is formed over the transistor. One or more first trenches are formed to the sources and drains of the first gates by removing the second insulating material between the insulating mandrels. A second trench is formed to the second gate by removing portions of the first and second insulating materials above the second gate. The first trenches and the second trench are filled with conductive material to form first contacts to the sources and drains of the first gates and a second contact to the second gate. | 07-17-2014 |