Abstract: A method for fabricating a semiconductor device is disclosed. An exemplary method includes receiving an integrated circuit (IC) layout design including a target pattern on a grid. The method further includes receiving a multiple-grid structure. The multiple-grid structure includes a number of exposure grid segments offset one from the other by an offset amount in a first direction. The method further includes performing a multiple-grid exposure to expose the target pattern on a substrate and thereby form a circuit feature pattern on the substrate. Performing the multiple-grid exposure includes scanning the substrate with the multiple-grid structure in a second direction such that a sub-pixel shift of the exposed target pattern occurs in the first direction, and using a delta time (?t) such that a sub-pixel shift of the exposed target pattern occurs in the second direction.

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: 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: 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 method for electron-beam patterning includes forming a conductive material layer on a substrate; forming a bottom anti-reflective coating (BARC) layer on the conductive material layer; forming a resist layer on the BARC layer; and directing an electron beam (e-beam) to the sensitive resist layer for an electron beam patterning process. The BARC layer is designed such that a top electrical potential of the resist layer is substantially zero during the e-beam patterning process.

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: A device for reflective electron-beam lithography and methods of producing the same are described. The device includes a substrate, a plurality of conductive layers formed on the substrate, which are parallel to each other and separated by insulating pillar structures, and a plurality of apertures in each conductive layer. Apertures in each conductive layer are vertically aligned with the apertures in other conductive layers and a periphery of each aperture includes conductive layers that are suspended.

Abstract: A method of data preparation in lithography processes is described. The method includes providing an integrated circuit (IC) layout design in a graphic database system (GDS) grid, converting the IC layout design GDS grid to a first exposure grid, applying a non-directional dither technique to the first exposure, coincident with applying dithering to the first expose grid, applying a grid shift to the first exposure grid to generate a grid-shifted exposure grid and applying a dither to the grid-shifted exposure grid, and adding the first exposure grid (after receiving dithering) to the grid-shifted exposure grid (after receiving dithering) to generate a second exposure grid.

Abstract: An energy transforming apparatus has a controllable magnetic power gathering device and a transforming device to transform the non-continuous kinetic energy into electrical power to store in the power storage assembly. The controllable magnetic power gathering device has a non-continuous moved or linear reciprocating moved input end, a continuous rotating output end and a controllable energy-adjusting end, etc, to transform the impulse momentum into the continuous kinetic energy with the differential motion and using the non-contacting magnetic wheel transmission assembly to protect the overload effect. The transforming device has an energy transforming assembly, a circuit adjustment assembly and a power storage assembly. The circuit adjustment assembly is electrically connected with the energy transforming assembly to control the energy transforming assembly to transform the kinetic energy into electrical power.

Abstract: The present disclosure provides a photomask. The photomask includes a substrate. The photomask also includes a plurality of patterns disposed on the substrate. Each pattern is phase shifted from adjacent patterns by different amounts in different directions. The present disclosure also includes a method for performing a lithography process. The method includes forming a patternable layer over a wafer. The method also includes performing an exposure process to the patternable layer. The exposure process is performed at least in part through a phase shifted photomask. The phase shifted photomask contains a plurality of patterns that are each phase shifted from adjacent patterns by different amounts in different directions. The method includes patterning the patternable layer.

Abstract: A lithography apparatus includes an imaging lens module, a substrate table positioned underlying the imaging lens module and configured to hold a substrate, and a cleaning module adapted to clean the lithography apparatus. The cleaning module comprises one inlet and one outlet for providing a cleaning fluid to and from a portion of the lithography apparatus to be cleaned, and an ultrasonic unit configured to provide ultrasonic energy to the cleaning fluid.

Abstract: Disclosed is a photomask having a wavelength-reducing material that may be used during photolithographic processing. In one example, the photomask includes a transparent substrate, an absorption layer having at least one opening, and a layer of wavelength-reducing material (WRM) placed into the opening. The thickness of the WRM may range from approximately a thickness of the absorption layer to approximately ten times the wavelength of light used during the photolithographic processing. In another example, the photomask includes at least one antireflection coating (ARC) layer.

Abstract: The present disclosure provide one embodiment of a method of 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 area S1 to generate a data grid having a second pixel area S2 that is equal to n2*S1, wherein the pattern generator includes a multi-segment structure having multiple grid segments, wherein the grid segments includes a first set of grid segments and a second set of grid segments, each of the first set of grid segments being configured to have an offset 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 of the second set of grid segments is controlled to have a time delay.

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 light guide plate, backlight module installed with the same and method of guiding light utilizing the same are provided. The light guide plate has a bottom surface, a light outlet surface opposite to the bottom surface, and a light inlet surface at least connected with the light outlet surface. A light is introduced to the light inlet surface and transmitted in the light guide plate. The light guide plate comprises a light transmissive substrate installed with at least one through hole, and a first slot installed on the light transmissive substrate and arranged at the periphery of the through hole.

Abstract: A backlight module comprises a light emitting element and a light guide panel having a light output surface in which the light output surface is with a first side, a second side, a through hole, a recess and plural microstructure rows. The microstructure rows are arranged on the light output surface, and the extending direction thereof is parallel to the extending direction of the first side. The through hole is installed between any two adjacent microstructure rows. The light emitting element is disposed in the recess in a central zone of the light output surface, and arranged to emit lights towards the second side. One major light emitting axis of the light emitting element deviates from the through hole.

Abstract: A method for fabricating a semiconductor device is disclosed. An exemplary method includes receiving an integrated circuit (IC) layout design including a target pattern on a grid. The method further includes receiving a multiple-grid structure. The multiple-grid structure includes a number of exposure grid segments offset one from the other by an offset amount in a first direction. The method further includes performing a multiple-grid exposure to expose the target pattern on a substrate and thereby form a circuit feature pattern on the substrate. Performing the multiple-grid exposure includes scanning the substrate with the multiple-grid structure in a second direction such that a sub-pixel shift of the exposed target pattern occurs in the first direction, and using a delta time (?t) such that a sub-pixel shift of the exposed target pattern occurs in the second direction.

Abstract: The present disclosure involves a method of data preparation in lithography processes. The method of data preparation includes providing an integrated circuit (IC) layout design in a graphic database system (GDS) grid, and converting the IC layout design GDS grid to a second exposure grid by applying an error diffusion and a grid shift technique to a sub-pixel exposure grid.

Abstract: A method of data preparation in lithography processes is described. The method includes providing an integrated circuit (IC) layout design in a graphic database system (GDS) grid, converting the IC layout design GDS grid to a first exposure grid, applying a non-directional dither technique to the first exposure, coincident with applying dithering to the first expose grid, applying a grid shift to the first exposure grid to generate a grid-shifted exposure grid and applying a dither to the grid-shifted exposure grid, and adding the first exposure grid (after receiving dithering) to the grid-shifted exposure grid (after receiving dithering) to generate a second exposure grid.

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.