Abstract: A pattern generator includes a mirror array plate having a mirror, at least one electrode plate disposed over the mirror array plate, a lens let disposed over the mirror, and at least one insulator layer sandwiched between the mirror array plate and the electrode plate. The electrode plate includes a first conducting layer and a second conducting layer. The lens let has a non-straight sidewall formed in the electrode plate. The pattern generator further includes at least one insulator sandwiched between two electrode plates. The non-straight sidewall can be a U-shaped sidewall or an L-shaped sidewall.

Abstract: Immersion lithography system and method using a sealed wafer bottom are described. One embodiment is an immersion lithography apparatus comprising a lens assembly comprising an imaging lens and a wafer stage for retaining a wafer beneath the lens assembly, the wafer stage comprising a seal ring disposed on a seal ring frame along a top edge of the wafer retained on the wafer stage, the seal ring for sealing a gap between an edge of the wafer and the wafer stage. The embodiment further includes a fluid tank for retaining immersion fluid, the fluid tank situated with respect to the wafer stage for enabling full immersion of the wafer retained on the wafer stage in the immersion fluid and a cover disposed over at least a portion of the fluid tank for providing a temperature-controlled, fluid-rich environment within the fluid tank fluid-rich environment within the fluid tank.

Abstract: A pattern generator includes a minor array plate having a mirror, at least one electrode plate disposed over the minor array plate, a lens let disposed over the minor, and at least one insulator layer sandwiched between the mirror array plate and the electrode plate. The electrode plate includes a first conducting layer and a second conducting layer. The lens let has a non-straight sidewall formed in the electrode plate. The pattern generator further includes at least one insulator sandwiched between two electrode plates. The non-straight sidewall can be a U-shaped sidewall or an L-shaped sidewall.

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 a method of increasing the wafer throughput by an electron beam lithography system. The method includes scanning a wafer using the maximum scan slit width (MSSW) of the electron beam writer. By constraining the integrated circuit (IC) field size to allow the MSSW to cover a complete field, the MSSW is applied to decrease the scan lanes of a wafer and thereby increase the throughput. When scanning the wafer with the MSSW, the next scan lane data can be rearranged and loaded into a memory buffer. Thus, once one scan lane is finished, the next scan lane data in the memory buffer is read for scanning.

Abstract: The present disclosure provides a lithography system comprising a radiation source and an exposure tool including a plurality of exposure columns densely packed in a first direction. Each exposure column includes an exposure area configured to pass the radiation source. The system also includes a wafer carrier configured to secure and move one or more wafers along a second direction that is perpendicular to the first direction, so that the one or more wafers are exposed by the exposure tool to form patterns along the second direction. The one or more wafers are covered with resist layer and aligned in the second direction on the wafer carrier.

Abstract: A method of quantifying a lithographic proximity effect and determining a lithographic exposure dosage is disclosed. In an exemplary embodiment, the method for determining an exposure dosage comprises receiving a design database including a plurality of features intended to be formed on a workpiece. A target region of the design database is defined such that the target region includes a target feature. A region of the design database proximate to the target region is also defined. An approximation for the region is determined, where the approximation represents an exposed area within the region. A proximity effect of the region upon the target feature is determined based on the approximation for the region. A total proximity effect for the target feature is determined based on the determined proximity effect of the region upon the target feature.

Abstract: The present disclosure provides one embodiment of an integrated circuit (IC) method. The method includes receiving an IC design layout having a feature; fracturing the feature into a plurality of polygons that includes a first polygon; assigning target points to edges of the first polygon; calculating corrected exposure doses to the first polygon, wherein each of the correct exposure doses is determined based on a respective one of the target points by simulation; determining a polygon exposure dose to the first polygon based on the corrected exposure doses; and preparing a tape-out data for lithography patterning, wherein the tape-out data defines the plurality of polygons and a plurality of polygon exposure doses paired with the plurality of polygons.

Abstract: A method of quantifying a lithographic proximity effect and determining a lithographic exposure dosage is disclosed. In an exemplary embodiment, the method for determining an exposure dosage comprises receiving a design database including a plurality of features intended to be formed on a workpiece. A target region of the design database is defined such that the target region includes a target feature. A region of the design database proximate to the target region is also defined. An approximation for the region is determined, where the approximation represents an exposed area within the region. A proximity effect of the region upon the target feature is determined based on the approximation for the region. A total proximity effect for the target feature is determined based on the determined proximity effect of the region upon the target feature.

Abstract: A method and material layer for forming a pattern are disclosed. The method includes providing a substrate; forming a first material layer over the substrate; forming a second material layer over the first material layer, wherein the second material layer comprises a photoacid generator and a photobase generator; and exposing one or more portions of the second material layer.

Abstract: The present disclosure provides a method for image dithering. The method includes providing a polygon related to an integrated circuit (IC) layout design in a graphic database system (GDS) grid; converting the polygon to an intensity map in the GDS grid, the intensity map including a group of partial pixels and a group of full pixels; performing a first quantization process to a partial pixel to determine a first error; applying the first error to one or more full pixels; performing a second quantization process to a full pixel to determine a second error; and distributing the second error to one or more full pixels. The partial pixels correspond to pixels partially covered by the polygon, and the full pixels correspond to pixels fully covered by the polygon.

Abstract: The present disclosure provides one embodiment of an integrated circuit (IC) method. The method includes receiving an IC design layout having a feature; fracturing the feature into a plurality of polygons that includes a first polygon; assigning target points to edges of the first polygon; calculating corrected exposure doses to the first polygon, wherein each of the correct exposure doses is determined based on a respective one of the target points by simulation; determining a polygon exposure dose to the first polygon based on the corrected exposure doses; and preparing a tape-out data for lithography patterning, wherein the tape-out data defines the plurality of polygons and a plurality of polygon exposure doses paired with the plurality of polygons.

Abstract: A method for electron-beam writing to a medium includes positioning the medium within an e-beam writing machine so that the medium is supported by a stage and is exposed to an e-beam source. The method also includes writing a pattern to the medium using a plurality of independently-controllable beams of the e-beam source, in which the pattern comprises a plurality of parallel strips. Each of the parallel strips is written using multiple ones of the independently-controllable beams.

Abstract: The present disclosure provides an embodiment of a method, for a lithography process for reducing a critical dimension (CD) by a factor n wherein n<1. The method includes providing a pattern generator having a first pixel size S1 to generate an alternating data grid having a second pixel size S2 that is <S1, wherein the pattern generator includes multiple grid segments configured to offset from each other in a first direction; and scanning the pattern generator in a second direction perpendicular to the first direction during the lithography process such that each subsequent segment of the grid segments is controlled to have a time delay relative to a preceding segment of the grid segments.

Abstract: A keyboard comprises a key module and a backlight module in which the key module comprises a light-transmissive key part and an electric circuit substrate, and the backlight module comprises a light guide plate, a reflection unit and at least one light source. The backlight module is disposed between the key part and the electric circuit substrate. Thus, lights emitted by the light source are projected into the light guide plate from the lateral side of the light guide plate, and the lights are reflected by the reflection unit for directly passing through the light output surface of the light guide plate and the key part.

Abstract: The present disclosure describes a mask. The mask includes a low thermal expansion material (LTEM) substrate, at least two absorber layers, and a spacer layer separating the two absorber layers. The first absorber layer is deposited over the LTEM substrate. The mask further includes a topcoat layer over the absorber layer. A thickness of the spacer layer is approximately equal to a height of a topography feature on a wafer substrate multiplied by the square of a demagnification of an objective lens. The absorber layers include staged patterns.

Abstract: The present invention relates to a backlight module and a manufacturing method thereof. The backlight module comprises a thin film unit, a light guide unit, an insulation layer and at least a light source. The thin film unit is installed with a first circuit. The light guide unit is installed with a second circuit. The insulation layer is installed between the thin film unit and the light guide unit. The light source is electrically connected to the first circuit, and the light thereof projects into the light guide unit.

Abstract: An electron beam lithography method and apparatus for improving throughput is disclosed. An exemplary lithography method includes receiving a pattern layout having a pattern layout dimension; shrinking the pattern layout dimension; and overexposing a material layer to the shrunk pattern layout dimension, thereby forming the pattern layout having the pattern layout dimension on the material layer.

Abstract: A lithography apparatus generates a tunable magnetic field to facilitate processing of photoresist. The lithography apparatus includes a chamber and a substrate stage in the chamber operable to hold a substrate. A magnetic module provides a magnetic field to the substrate on the substrate stage. The magnetic module is configured to provide the magnetic field in a tunable and alternating configuration with respect to its magnitude and frequency. The magnetic field is provided to have a gradient in magnitude along a Z-axis that is perpendicular to the substrate stage to cause magnetically-charged particles disposed over the substrate stage to move up and down along the Z-axis. The lithography apparatus also includes a radiation energy source and an objective lens configured to receive radiation energy from the radiation energy source and direct the radiation energy toward the substrate positioned on the substrate stage.

Abstract: An electron beam lithography method and apparatus for improving throughput is disclosed. An exemplary lithography method includes receiving a pattern layout having a pattern layout dimension; shrinking the pattern layout dimension; and overexposing a material layer to the shrunk pattern layout dimension, thereby forming the pattern layout having the pattern layout dimension on the material layer.