Abstract: The present invention increases the number of characters available on a stencil for charged particle beam lithography. A stencil for charged particle beam lithography is disclosed, comprising two character projection (CP) characters, wherein the blanking areas for the two CP characters overlap. A stencil is also disclosed comprising two CP characters with one or more optional characters between the two characters, wherein the optional characters can form meaningful patterns on a surface only in combination with one of the two characters. A stencil is also disclosed wherein the blanking area of a CP character extends beyond the boundary of the stencil's available character area. Methods for design of the aforementioned stencils are also disclosed.

Abstract: A character projection charged particle beam writer system is disclosed comprising a variable magnification reduction lens which will allow different shot magnifications on a shot by shot basis. A method for fracturing or mask data preparation or optical proximity correction is also disclosed comprising assigning a magnification to each calculated charged particle beam writer shot. A method for forming a pattern on a surface is also disclosed comprising using a charged particle beam writer system and varying the magnification from shot to shot. A method for manufacturing an integrated circuit using optical lithography is also disclosed, comprising using a charged particle beam writer system to form a pattern on a reticle, and varying the magnification of the charged particle beam writer system from shot to shot.

Abstract: A method and system for optimization of an image to be printed on a substrate using optical lithography is disclosed in which a set of charged particle beam shots, some of which overlap, is determined so as to form a target pattern on a surface such as a reticle. The charged particle beam shots are simulated to determine the pattern that would be formed on the surface. Next, a substrate image is calculated from the simulated surface pattern. One or more shots in the set of shots are then modified to improve the calculated substrate image.

Abstract: A method for fracturing or mask data preparation or proximity effect correction of a pattern to be formed on a surface is disclosed in which a plurality of variable shaped beam (VSB) shots are determined, and in which charged particle beam simulation is used to calculate the pattern which the plurality of VSB shots will form on the surface. At least two shots in the plurality of VSB shots overlap each other. In some embodiments, assigned dosages of at least two shots differ before proximity effect correction (PEC). In other embodiments an optimization technique may be used.

Abstract: In the field of semiconductor production using shaped beam charged particle beam lithography, a pattern is formed on a surface by dragging a charged particle beam across the surface in a single extended shot to form a track. In some embodiments, the track may form a straight path, a curved path, or a perimeter of a curvilinear shape. In other embodiments, the width of the track may be altered by varying the velocity of the dragged beam. The techniques may be used for manufacturing an integrated circuit by dragging a charged particle beam across a resist-coated wafer to transfer a pattern to the wafer, or by dragging a charged particle beam across a reticle, where the reticle is used to manufacture a photomask which is then used to transfer a pattern to a wafer using an optical lithographic process.

Abstract: A stencil for character projection (CP) charged particle beam lithography and a method for manufacturing the stencil is disclosed, where the stencil contains two circular characters, where each character is capable of forming patterns on a surface in a range of sizes by using different dosages, and where the size ranges for the two characters is continuous. A method for forming circular patterns on a surface using variable-shaped beam (VSB) shots of different dosages is also disclosed. A method for forming circular patterns on a surface using a set of shots, where all of the shots comprise dosages, is also disclosed.

Abstract: Various embodiments of the present invention relate to particle beam writing to fabricate an integrated circuit on a wafer. In various embodiments, cell projection (CP) cell library information is stored in the form of a data structure. Subsequently, the CP cell library information is referenced by a writing system. The patterns are written on the wafer depending on the referenced CP cell library.

Abstract: In the field of semiconductor production using shaped charged particle beam lithography, a method and system for fracturing or mask data preparation or proximity effect correction is disclosed, wherein a series of curvilinear character projection shots are determined for a charged particle beam writer system, such that the set of shots can form a continuous track, possibly of varying width, on a surface. In some embodiments, characteristics of the continuous track will be within a predetermined tolerance.

Abstract: In a method for fracturing or mask data preparation or mask process correction for charged particle beam lithography, a plurality of shots are determined that will form a pattern on a surface, where shots are determined so as to reduce sensitivity of the resulting pattern to changes in beam blur (?f). At least some shots in the plurality of shots overlap other shots. In some embodiments, ?f is reduced by controlling the amount of shot overlap in the plurality of shots, either during initial shot determination, or in a post-processing step. The reduced sensitivity to ?f expands the process window for the charged particle beam lithography process.

Abstract: A method for fracturing or mask data preparation or optical proximity correction is disclosed, wherein a plurality of variable shaped beam (VSB) shots are determined for at least one exposure pass, where the plurality of VSB shots forms a line pattern which is at a diagonal to the axes of a Cartesian coordinate plane, and where at least two neighboring shots in the same exposure pass overlap. Methods for manufacturing a surface using charged particle beam lithography and for manufacturing an integrated circuit using an optical lithography process are also disclosed.

Abstract: In the field of semiconductor production using charged particle beam lithography, a method and system for fracturing or mask data preparation or proximity effect correction is disclosed, wherein base dosages for a plurality of exposure passes are different from each other. Methods for manufacturing a reticle and manufacturing an integrated circuit are also disclosed, wherein a plurality of charged particle beam exposure passes are used, with base dosage levels being different for different exposure passes.

Abstract: A method for fracturing or mask data preparation or proximity effect correction of a pattern to be formed on a surface is disclosed in which a plurality of variable shaped beam (VSB) shots are determined, and in which charged particle beam simulation is used to calculate the pattern which the plurality of VSB shots will form on the surface. At least two shots in the plurality of VSB shots overlap each other. In some embodiments, assigned dosages of at least two shots differ before proximity effect correction (PEC). In other embodiments an optimization technique may be used embodiments.

Abstract: A method and system for fracturing or mask data preparation or proximity effect correction is disclosed in which a series of charged particle beam shots is determined, where the series of shots is capable of forming a continuous non-manhattan track on a surface, such that the non-manhattan track has a line width roughness (LWR) which nearly equals a target LWR. A method and system for fracturing or mask data preparation or proximity effect correction is also disclosed in which at least two series of shots are determined, where each series of shots is capable of forming a continuous non-manhattan track on a surface, and where the space between tracks has space width roughness (SWR) which nearly equals a target SWR.

Abstract: In the field of semiconductor production using shaped charged particle beam lithography, a method and system for fracturing or mask data preparation or proximity effect correction is disclosed, wherein a plurality of shots of circular or nearly-circular character projection characters, having at least two shots that overlap, can form a non-circular pattern on a surface. Methods for manufacturing a reticle and for manufacturing a substrate such as a silicon wafer by forming non-circular patterns on a surface using a plurality of circular or nearly-circular character projection shots, where at least two shots overlap, is also disclosed.

Abstract: A method for optical proximity correction (OPC) of a desired pattern for a substrate is disclosed in which a plurality of variable shaped beam (VSB) shots are determined which can form on a surface an OPC-corrected version of the desired substrate pattern. Shots within the plurality of VSB shots are allowed to overlap each other. Dosages of the shots may also be allowed to vary with respect to each other. The union of the plurality of shots may deviate from the OPC-corrected version of the desired pattern for the substrate. In some embodiments, optimization may be used to minimize shot count. In other embodiments, the plurality of shots may be optionally selected from one or more pre-computed VSB shots or groups of VSB shots, that is, glyphs. A method for creating glyphs is also disclosed, in which patterns that would result on a surface from one or a group of VSB shots are pre-calculated.

Abstract: A method and system for fracturing or mask data preparation are disclosed which can reduce the critical dimension variation of patterns formed on a resist-coated surface using particle beam lithography by providing a higher peak dosage near the perimeter of the patterns than in the interiors of the patterns.

Abstract: A method and system for fracturing or mask data preparation are presented in which overlapping shots are generated to increase dosage in selected portions of a pattern, thus improving the fidelity and/or the critical dimension variation of the transferred pattern. In various embodiments, the improvements may affect the ends of paths or lines, or square or nearly-square patterns. Simulation is used to determine the pattern that will be produced on the surface.

Abstract: A method and system for fracturing or mask data preparation are presented in which overlapping shots are generated to increase dosage in selected portions of a pattern, thus improving the fidelity and/or the critical dimension variation of the transferred pattern. In various embodiments, the improvements may affect the ends of paths or lines, or square or nearly-square patterns. Simulation is used to determine the pattern that will be produced on the surface.

Abstract: A method and system for fracturing or mask data preparation or optical proximity correction or proximity effect correction or mask process correction is disclosed in which a set of shaped beam shots is determined that is capable of forming a pattern on a surface, where the set of shots provides different dosages to different parts of the pattern, and where the dose margin from the set of shots is calculated. A method for forming patterns on a surface is also disclosed.

Abstract: A method and system for fracturing or mask data preparation or optical proximity correction or proximity effect correction or mask process correction is disclosed in which a set of shaped beam shots is determined that is capable of forming a pattern on a surface, where a plurality of shots in the same exposure pass overlap, and where the dose margin from the set of shots is calculated. A method for forming patterns on a surface is also disclosed.