Abstract: The present disclosure provides a method for forming patterns in a semiconductor device. The method includes providing a substrate and a patterning-target layer over the substrate; patterning the patterning-target layer to form a main pattern; forming a middle layer over the patterning-target layer and a hard mask layer over the middle layer; patterning the hard mask layer to form a first cut pattern; patterning the hard mask layer to form a second cut pattern, a combined cut pattern being formed in the hard mask layer as a union of the first cut pattern and the second cut pattern; transferring the combined cut pattern to the middle layer; etching the patterning-target layer using the middle layer as an etching mask to form a final pattern in the patterning-target layer. In some embodiments, the final pattern includes the main pattern subtracting an intersection portion between main pattern and the combined cut pattern.

Abstract: The present disclosure provides a method for forming patterns in a semiconductor device. In accordance with some embodiments, the method includes providing a substrate and a patterning-target layer over the substrate; forming one or more mandrel patterns over the patterning-target layer; forming an opening in a resist layer by removing a first mandrel pattern and removing a portion of the resist layer that covers the first mandrel pattern; forming spacers adjacent to sidewalls of a second mandrel pattern; removing the second mandrel pattern to expose the spacers; forming a patch pattern over the spacers and aligned with the opening; etching the patterning-target layer using the patch pattern and the spacers as mask elements to form final patterns; and removing the patch pattern and the spacers to expose the final patterns.

Abstract: In one embodiment, a method for extracting systematic defects is provided. The method includes inspecting a wafer outside a process window to obtain inspection data, defining a defect pattern from the inspection data, filtering defects from design data using a pattern search for the defined defect pattern within the design data, inspecting defects inside the process window with greater sensitivity than outside the process window, and determining systematic defects inside the process window. A computer readable storage medium, and a system for extracting systematic defects are also provided.

Abstract: The present disclosure describes methods for transferring a desired layout into a target layer on a semiconductor substrate. An embodiment of the methods includes forming a first desired layout feature as a first line over the target layer; forming a spacer around the first line; depositing a spacer-surrounding material layer; removing the spacer to form a fosse pattern trench surrounding the first line; and transferring the fosse pattern trench into the target layer to form a fosse feature trench in the target layer, wherein the fosse feature trench surrounds a first portion of the target layer that is underneath a protection layer. In some embodiments, the method further includes patterning a second desired layout feature of the desired layout into the target layer wherein the fosse feature trench and the protection layer serve to self-align the second desired layout feature with the first portion of the target layer.

Abstract: A method embodiment for patterning a semiconductor device includes patterning a dummy layer over a hard mask to form one or more dummy lines. A sidewall aligned spacer is conformably formed over the one or more dummy lines and the hard mask. A first reverse material layer is formed over the sidewall aligned spacer. A first photoresist is formed and patterned over the first reverse material layer. The first reverse material layer using the first photoresist as a mask, wherein the sidewall aligned spacer is not etched. The one or more dummy lines are removed, and the hard mask is patterned using the sidewall aligned spacer and the first reverse material layer as a mask. A material used for forming the sidewall aligned spacer has a higher selectivity than a material used for forming the first reverse material layer.

Abstract: The present disclosure describes methods for transferring a desired layout into a target layer. The method includes a step of forming a spacer, having a second width, around a first and a second desired layout feature pattern of the desired layout over a semiconductor substrate. The first desired layout feature pattern is formed using a first sub-layout and the second desired layout feature pattern is formed using a second sub-layout. The first and second desired layout feature patterns are separated by a first width. The method further includes forming a third desired layout feature pattern according to a third sub-layout. The third desired layout feature pattern is shaped in part by the spacer. The method further includes removing the spacer from around the first and second desired layout feature pattern and etching the target layer using the first, second, and third layout feature patterns as masking features.

Abstract: The present disclosure provides a method of patterning a target material layer over a semiconductor substrate. The method includes steps of: forming a plurality of first features over the target material layer using a first sub-layout, with each first feature having sidewalls; forming a plurality of spacer features, with each spacer feature conforming to the sidewalls of one of the first features and having a spacer width; and forming a plurality of second features over the target material layer using a second sub-layout. The method further includes steps of removing the plurality of spacer features from around each first feature and patterning the target material layer using the plurality of first features and the plurality of second features. Other methods and associated patterned semiconductor wafers are also provided herein.

Abstract: A method including forming a trench over a layer disposed on a semiconductor substrate. The trench is filled with a first material to form a filled trench. A feature of a second material is formed over the filled trench. The feature is disposed over the filled trench and extends along two opposing sidewalls of the filled trench to a top surface of the layer. The feature is then planarized to expose a top surface of the filled trench and provide a first portion of the feature adjacent a first sidewall of the two opposing sidewalls of the filled trench and a second portion of the feature adjacent a second sidewall of the two opposing sidewalls of the filled trench. The first and second portions of the feature are used to define a dimension of an interconnect feature disposed over the semiconductor substrate.

Abstract: A method of forming a target pattern includes forming a first material layer on a substrate; performing a first patterning process using a first layout to form a first plurality of trenches in the first material layer; performing a second patterning process using a second layout to form a second plurality of trenches in the first material layer; forming spacer features on sidewalls of both the first plurality of trenches and the second plurality of trenches, the spacer features having a thickness; removing the first material layer; etching the substrate using the spacer features as an etch mask; and thereafter removing the spacer features. The target pattern is to be formed with the first layout and the second layout.

Abstract: The present disclosure provides a method for forming patterns in a semiconductor device. In accordance with some embodiments, the method includes providing a substrate, a patterning-target layer over the substrate, and a hard mask layer over the patterning-target layer; forming a first pattern in the hard mask layer; removing a trim portion from the first pattern in the hard mask layer to form a trimmed first pattern; forming a first resist layer over the hard mask layer; forming a main pattern in the first resist layer; and etching the patterning-target layer using the main pattern and the trimmed first pattern as etching mask elements to form a final pattern in the patterning-target layer. In some embodiments, the final pattern includes the main pattern subtracting a first overlapping portion between the main pattern and the trimmed first pattern.

Abstract: The present disclosure provides a method of systematic defect extraction. Primary and secondary areas are defined in a wafer layout. A plurality of defects is identified by a first wafer inspection for an outside-process-window wafer. Defects located in the secondary area are removed. Defects associated with non-critical semiconductor features are also removed via a grouping process. Sensitive regions are defined around defects associated with critical semiconductor features. A second inspection is then performed on the sensitive regions for an inside-process-window wafer, thereby identifying a plurality of potentially systematic defects. Thereafter, a Scanning Electron Microscopy (SEM) process is performed to determine whether the defects in the sensitive regions of the inside-process-window wafer are true systematic defects.

Abstract: The present disclosure provides a method for forming patterns in a semiconductor device. In accordance with some embodiments, the method includes providing a substrate and a patterning-target layer over the substrate; forming one or more mandrel patterns over the patterning-target layer; forming an opening in a resist layer by removing a first mandrel pattern and removing a portion of the resist layer that covers the first mandrel pattern; forming spacers adjacent to sidewalls of a second mandrel pattern; removing the second mandrel pattern to expose the spacers; forming a patch pattern over the spacers and aligned with the opening; etching the patterning-target layer using the patch pattern and the spacers as mask elements to form final patterns; and removing the patch pattern and the spacers to expose the final patterns.

Abstract: Embodiments of the present disclosure include self-alignment of two or more layers and methods of forming the same. An embodiment is a method for forming a semiconductor device including forming at least two gates over a substrate, forming at least two alignment structures over the at least two gates, forming spacers on the at least two alignment structures, and forming a first opening between a pair of the at least two alignment structures, the first opening extending a first distance from a top surface of the substrate. The method further includes filling the first opening with a first conductive material, forming a second opening between the spacers of at least one of the at least two alignment structures, the second opening extending a second distance from the top surface of the substrate, and filling the second opening with a second conductive material.

Abstract: A method including forming a first pattern having a first and second feature is described. A masking layer is formed over the first and second features. An opening is patterned in the masking layer. The opening can extend over at least one of the first and second features. The patterned opening is then used to form a third feature (filled trench) between the first and second features. A second pattern is then formed that includes a fourth feature and fifth feature each having an edge defined by the third feature. The first, second, fourth and fifth features may then be used to pattern an underlying layer over the semiconductor substrate.

Abstract: A method embodiment for patterning a semiconductor device includes patterning a dummy layer over a hard mask to form one or more dummy lines. A sidewall aligned spacer is conformably formed over the one or more dummy lines and the hard mask. A first reverse material layer is formed over the sidewall aligned spacer. A first photoresist is formed and patterned over the first reverse material layer. The first reverse material layer using the first photoresist as a mask, wherein the sidewall aligned spacer is not etched. The one or more dummy lines are removed, and the hard mask is patterned using the sidewall aligned spacer and the first reverse material layer as a mask. A material used for forming the sidewall aligned spacer has a higher selectivity than a material used for forming the first reverse material layer.

Abstract: The present disclosure provides a method for forming patterns in a semiconductor device. In accordance with some embodiments, the method includes providing a substrate and a patterning-target layer over the substrate; forming one or more mandrel patterns over the patterning-target layer; forming an opening in a resist layer by removing a first mandrel pattern and removing a portion of the resist layer that covers the first mandrel pattern; forming spacers adjacent to sidewalls of a second mandrel pattern; removing the second mandrel pattern to expose the spacers; forming a patch pattern over the spacers and aligned with the opening; etching the patterning-target layer using the patch pattern and the spacers as mask elements to form final patterns; and removing the patch pattern and the spacers to expose the final patterns.

Abstract: An embodiment of a feed-forward method of determining a photomask pattern is provided. The method includes providing design data associated with an integrated circuit device. A thickness of a coating layer to be used in fabricating the integrated circuit device is predicted based on the design data. This prediction is used to generate a gradating pattern. A photomask is formed having the gradating pattern.

Abstract: A method for optimizing mask assignment for multiple pattern processes includes, through a computing system, defining which of a number of vias to be formed between two metal layers are critical based on metal lines interacting with the vias, determining overlay control errors for an alignment tree that defines mask alignment for formation of the two metal layers and the vias, and setting both the alignment tree and mask assignment for the vias so as to maximize the placement of critical vias on masks that have less overlay control error to the masks forming the relevant metal lines.

Abstract: The present disclosure provides one embodiment of a method for an integrated circuit (IC). The method includes forming a mandrel pattern on a substrate by a first lithography process; forming a first spacer pattern on sidewalls of the mandrel pattern; removing the mandrel pattern; forming a second spacer pattern on sidewalls of the first spacer pattern; removing the first spacer pattern; and etching the substrate using the second spacer pattern as an etch mask.

Abstract: Embodiments of the present disclosure include self-alignment of two or more layers and methods of forming the same. An embodiment is a method for forming a semiconductor device including forming at least two gates over a substrate, forming at least two alignment structures over the at least two gates, forming spacers on the at least two alignment structures, and forming a first opening between a pair of the at least two alignment structures, the first opening extending a first distance from a top surface of the substrate. The method further includes filling the first opening with a first conductive material, forming a second opening between the spacers of at least one of the at least two alignment structures, the second opening extending a second distance from the top surface of the substrate, and filling the second opening with a second conductive material.