Abstract: A method of patterning a wafer using four areas with differing exposure characteristics is disclosed. Two areas are phase shifted relative to the other two areas in order to create unexposed areas on the integrated circuit. Two different areas have polarizations orthogonal to each other, are frequency shifted relative to the two other areas, or are exposed by light at a time different than the two other areas to form exposed areas on the integrated circuit. The exposed areas are subsequently removed from the integrated circuit. In one embodiment, the four areas are on the same mask. The use of four areas with differing exposure characteristics allows for the patterning of more complicated and smaller geometric patterns on the integrated circuit than traditional patterning methods.

Abstract: Selective placement of polishing dummy feature patterns, rather than indiscriminate placement of polishing dummy feature patterns, is used. Both low frequency (hundreds of microns and larger) and high frequency (10 microns and less) of topography changes are examined. The polishing dummy feature patterns can be specifically tailored to a semiconductor device and polishing conditions used in forming the semiconductor device. When designing an integrated circuit, polishing effects for the active features can be predicted. After polishing dummy feature pattern(s) are placed into the layout, the planarity can be examined on a local level (a portion but not all of the device) and a more global level (all of the device, devices corresponding to a reticle field, or even an entire wafer).

Abstract: A method of patterning a wafer using four areas with differing exposure characteristics is disclosed. Two areas are phase shifted relative to the other two areas in order to create unexposed areas on the integrated circuit. Two different areas have polarizations orthogonal to each other, are frequency shifted relative to the two other areas, or are exposed by light at a time different than the two other areas to form exposed areas on the integrated circuit. The exposed areas are subsequently removed from the integrated circuit. In one embodiment, the four areas are on the same mask. The use of four areas with differing exposure characteristics allows for the patterning of more complicated and smaller geometric patterns on the integrated circuit than traditional patterning methods.

Abstract: Selective placement of polishing dummy feature patterns, rather than indiscriminate placement of polishing dummy feature patterns, is used. Both low frequency (hundreds of microns and larger) and high frequency (10 microns and less) of topography changes are examined. The polishing dummy feature patterns can be specifically tailored to a semiconductor device and polishing conditions used in forming the semiconductor device. When designing an integrated circuit, polishing effects for the active features can be predicted. After polishing dummy feature pattern(s) are placed into the layout, the planarity can be examined on a local level (a portion but not all of the device) and a more global level (all of the device, devices corresponding to a reticle field, or even an entire wafer).

Abstract: Integrated circuit designs are continually shrinking in size. Lithographic processes are used to transfer these designs to a semiconductor substrate. These processes typically require that the exposure wavelength of light be shorter than the smallest dimension of the elements within the circuit design. When this is not the case, exposure energy such as light behaves more like a wave than a particle. Additionally, mask manufacturing, photoresist chemical diffusion, and etch effects cause pattern transfer distortions. The result is that circuit elements do not print as designed. To counter this effect the circuit designs themselves can be altered so that the final printed results better matches the initial desired design. The process of altering designs in this way is called Lithographic Proximity Correction (LPC). Square (142), cross (162), octagon (172), and hammerhead (202) serifs are added to integrated circuit designs by shape manipulation functions to perform two dimensional (2-D) LPC.

Abstract: Integrated circuit designs are continually shrinking in size. Lithographic processes are used to pattern these designs onto a semiconductor substrate. These processes typically require that the wavelength of exposure used during printing be significantly shorter than the smallest dimension of the elements within the circuit design. When this is not the case, the exposure radiation behaves more like a wave than a particle. Additionally, mask manufacturing, photoresist chemical diffusion and etch effects cause pattern transfer distortions. The result is that circuit elements do not print as designed. To counter this effect the designs themselves can be altered so that the final printed results better match the initial desired design. The process of altering designs in this way is called Lithographic Proximity Correction (LPC). Edge assist shapes and edge biasing features are added to integrated circuit designs by shape manipulation functions to perform one dimensional (1-D) LPC.

Abstract: A process for fabricating a semiconductor device includes the formation of a lithographic reticle (20) having a lithographic pattern (18) overlying a reticle substrate (10). In one embodiment, a reticle inspection database incorporates altered resolution assisting features (30,32) to inspect the lithographic pattern (18). The dimensional difference between the reticle inspection database and the lithographic reticle is substantially equal to the process bias realized during reticle fabrication. Inspection of the lithographic reticle (20) using a reticle inspection database containing altered resolution assisting features reduces the false detection of defects and provides increased sensitivity in the reticle inspection process.

Abstract: A process for designing and forming a reticle (40) as well as the manufacture of a semiconductor substrate (50) using that reticle (40). The present invention places outriggers (32, 34, 36) between features (30) in both dense and semi-dense feature patterns to assist in the patterning of device features. The width of the outriggers can be changed based on pitch and location between features in a semi-dense or dense feature pattern. In one embodiment, the outriggers can be manually or automatically inserted into the layout file after the locations of the attenuating features have been determined. The outriggers are not patterned on the substrate, but assist in forming resist features of uniform width.