Abstract: A method for reducing M3D effects on imaging is described. The method includes identifying points within a source plane of the photolithography system that are associated with pattern shifts resulting from diffraction of light off a photomask under an angle of incidence between an imaging beam of radiation and the mask normal, determining pattern shifts associated with the identified source plane points, and modifying the source to reduce the determined pattern shifts.

Abstract: Various implementations of the invention provide for generation of a high transmission phase shift mask layout through inverse lithography techniques. In various implementations of the present invention, a set of mask data having a plurality of pixels is generated. The transmission value associated with each pixel may then be determined through an inverse lithography technique. With various implementations of the invention, the inverse lithography technique identifies an objective function, minimizes the objective function in relation to a simulation of the optical lithographic process, such that the transmission value, which is greater than 6%, may be determined.

Abstract: Various implementations of the invention provide for generation of a high transmission phase shift mask layout through inverse lithography techniques. In various implementations of the present invention, a set of mask data having a plurality of pixels is generated. The transmission value associated with each pixel may then be determined through an inverse lithography technique. With various implementations of the invention, the inverse lithography technique identifies an objective function, minimizes the objective function in relation to a simulation of the optical lithographic process, such that the transmission value, which is greater than 6%, may be determined.

Abstract: Various implementations of the invention provide for generation of a high transmission phase shift mask layout through inverse lithography techniques. In various implementations of the present invention, a set of mask data having a plurality of pixels is generated. The transmission value associated with each pixel may then be determined through an inverse lithography technique. With various implementations of the invention, the inverse lithography technique identifies an objective function, minimizes the objective function in relation to a simulation of the optical lithographic process, such that the transmission value, which is greater than 6%, may be determined.

Abstract: A mask pattern for imaging a marker structure on a substrate with a lithographic apparatus, the marker structure being configured to determine optical alignment or overlay, includes constituent parts to define the marker structure. The constituent parts include a plurality of segments, each segment having substantially a size of a device feature and a segment shape. The mask pattern includes at least one assist feature located at a critical part of the segment shape. The at least one assist feature has substantially a size below a resolution of the lithographic projection and is configured to counteract optical aberrations or optical limitations generated in the lithographic projection at the critical part.

Abstract: A mask pattern for imaging a marker structure on a substrate with a lithographic apparatus, the marker structure being configured to determine optical alignment or overlay, includes constituent parts to define the marker structure. The constituent parts include a plurality of segments, each segment having substantially a size of a device feature and a segment shape. The mask pattern includes at least one assist feature located at a critical part of the segment shape. The at least one assist feature has substantially a size below a resolution of the lithographic projection and is configured to counteract optical aberrations or optical limitations generated in the lithographic projection at the critical part.