Abstract: The present disclosure provides a method for forming patterns in a semiconductor device. In accordance with some embodiments, the method includes providing a substrate and a patterning-target layer formed over the substrate; forming a first cut pattern in a first hard mask layer formed over the patterning-target layer; forming a second cut pattern in a second hard mask layer formed over the patterning layer, the first hard mask layer having a different etching selectivity from the second hard mask layer; selectively removing a portion of the second cut pattern in the second hard mask layer and a portion of the patterning-target layer within a first trench; and selectively removing a portion of the first cut pattern in the first hard mask layer and a portion of the patterning-target layer within a second trench.

Abstract: A system and method is provided for providing a thermal distribution on a workpiece during a lithographic process. The system provides a source of lithographic energy to workpiece, such as a workpiece having a lithographic film formed thereover. A workpiece support having a plurality of thermal devices embedded therein is configured to support the workpiece concurrent to an exposure of the workpiece to the lithographic energy. A controller individually controls a temperature of each of the plurality of thermal devices, therein controlling a specified temperature distribution across the workpiece associated with the exposure of the workpiece to the lithographic energy. Controlling the temperature of the thermal devices can be based on a model, a measured temperature of the workpiece, and/or a prediction of a temperature at one or more locations on the workpiece.

Abstract: Semiconductor devices disclosed herein have minimum spacings that correlate with spacer widths. An exemplary semiconductor device includes a substrate and a target layer disposed over the substrate. The target layer includes a first target feature, a second target feature, and a third target feature. The second target feature is spaced a first distance from the first target feature, and the third target feature is spaced a second distance from the first target feature. The first distance corresponds with a first width of a first spacer fabricated during a first spacer patterning process, and the second distance corresponds with a second width of a second spacer fabricated during a second spacer patterning process.

Abstract: The present disclosure provides a method for forming patterns in a semiconductor device. In accordance with some embodiments, the method includes providing a substrate, a patterning-target layer over the substrate, and a hard mask layer over the patterning-target layer; forming a first pattern in the hard mask layer; removing a trim portion from the first pattern in the hard mask layer to form a trimmed first pattern; forming a first resist layer over the hard mask layer; forming a main pattern in the first resist layer; and etching the patterning-target layer using the main pattern and the trimmed first pattern as etching mask elements to form a final pattern in the patterning-target layer. In some embodiments, the final pattern includes the main pattern subtracting a first overlapping portion between the main pattern and the trimmed first pattern.

Abstract: The present disclosure provides a system and a method for cash flow verification by a third-party payment platform. The system includes a server and a client device. The client device includes a network device, a storage device and a processor. The storage device is configured to store a plurality of programmed instructions and establish a client database. The processor is configured to execute the programmed instructions to generate execution history data, wherein the execution history data comprises cash flow history data, which can be produced by a third-party platform. While the network device is incapable of connecting the server through the Internet, the processor stores the execution history data in the client database; while the network device is capable of connecting the server through the Internet, the processor transmits the execution history data to the server through the network device for verification, and the verification comprises cash flow verification.

Abstract: Systems and methods are disclosed herein for enhancing lithography printability, and in particular, for enhancing image contrast. An exemplary method includes receiving an integrated circuit (IC) design layout and generating an exposure map based on the IC design layout. The IC design layout includes a target pattern to be formed on a workpiece, and the exposure map includes an exposure grid divided into dark pixels and bright pixels that combine to form the target pattern. The method further includes adjusting the exposure map to increase exposure dosage at edges of the target pattern. In some implementations, the adjusting includes locating an edge portion of the target pattern in the exposure map, where the edge portion has a corresponding bright pixel, and assigning exposure energy from at least one dark pixel to the corresponding bright pixel, thereby generating a modified exposure map.

Abstract: Provided is a method of fabricating a semiconductor device. An integrated circuit (IC) layout plan is obtained. The IC layout plan contains critical features and non-critical features. Locational information regarding a defect on a blank reticle is obtained. The blank reticle is a candidate reticle for being patterned with the IC layout plan. Based on the locational information regarding the defect and the IC layout plan, a determination is made that at some of the critical features will intersect with the defect if the blank reticle is patterned with the IC layout plan, regardless of whether the IC layout plan is globally manipulated or not before being patterned onto the blank reticle. In response to the determination, selected local portions of the IC layout plan are re-arranged such that none of the critical features will intersect with the defect if the blank reticle is patterned with the IC layout plan.

Abstract: Target optimization methods are disclosed herein for enhancing lithography printability. An exemplary method includes receiving an IC design layout for a target pattern, wherein the target pattern has a corresponding target contour; modifying the target pattern, wherein the modified target pattern has a corresponding modified target contour; and generating an optimized target pattern when the modified target contour achieves functionality of the target pattern as defined by a constraint layer. The method can further include defining a cost function based on the constraint layer, where the cost function correlates a spatial relationship between a contour of the target pattern and the constraint layer.

Abstract: An inverse animal feeder comprises a feeding device, a power controlling device and a tray. The feeding device comprises a cover plate and a feeding opening inside the cover plate. The power controlling device comprises a motor in a main frame, a power source and a controller for feeding automatically. The tray mounted below the power controlling device and in an outer frame, and the tray is driven by the motor. The outer frame has a plurality of through holes; the main frame is mounted between the cover plate and the outer frame; and the cover plate is connected to the main frame by holders. Additionally, the main frame has at least one fastening block and the outer frame has at least one fastening groove, so that the fastening groove is fastened to the fastening groove to connect the main frame and the outer frame.

Abstract: The present disclosure describes methods for transferring a desired layout into a target layer on a semiconductor substrate. An embodiment of the methods includes forming a first desired layout feature as a first line over the target layer; forming a spacer around the first line; depositing a spacer-surrounding material layer; removing the spacer to form a fosse pattern trench surrounding the first line; and transferring the fosse pattern trench into the target layer to form a fosse feature trench in the target layer, wherein the fosse feature trench surrounds a first portion of the target layer that is underneath a protection layer. In some embodiments, the method further includes patterning a second desired layout feature of the desired layout into the target layer wherein the fosse feature trench and the protection layer serve to self-align the second desired layout feature with the first portion of the target layer.

Abstract: An integrated circuit structure includes a first metal feature formed into a first dielectric layer, a second metal feature formed into a second dielectric layer, the second dielectric layer being disposed on said first dielectric layer, and a via connecting the first metal feature to the second metal feature, wherein a top portion of the via is offset from a bottom portion of the via.

Abstract: A system and method is provided for providing a thermal distribution on a workpiece during a lithographic process. The system provides a source of lithographic energy to workpiece, such as a workpiece having a lithographic film formed thereover. A workpiece support having a plurality of thermal devices embedded therein is configured to support the workpiece concurrent to an exposure of the workpiece to the lithographic energy. A controller individually controls a temperature of each of the plurality of thermal devices, therein controlling a specified temperature distribution across the workpiece associated with the exposure of the workpiece to the lithographic energy. Controlling the temperature of the thermal devices can be based on a model, a measured temperature of the workpiece, and/or a prediction of a temperature at one or more locations on the workpiece.

Abstract: The present disclosure provides one embodiment of an IC method that includes receiving an IC design layout including a first main feature and a second main feature; determining that the first main feature includes has a curvilinear-based shaped; determining that the second main feature has a polygon-based shape; and mapping a first portion of the IC design layout that includes the first main feature onto a polar coordinate and mapping a second portion of the IC design layout that includes the second main feature on onto a Cartesian coordinate.

Abstract: Target optimization methods are disclosed herein for enhancing lithography printability. An exemplary method includes receiving an IC design layout for a target pattern, wherein the target pattern has a corresponding target contour; modifying the target pattern, wherein the modified target pattern has a corresponding modified target contour; and generating an optimized target pattern when the modified target contour achieves functionality of the target pattern as defined by a constraint layer. The method can further include defining a cost function based on the constraint layer, where the cost function correlates a spatial relationship between a contour of the target pattern and the constraint layer.

Abstract: Systems and methods are disclosed herein for enhancing lithography printability, and in particular, for enhancing image contrast. An exemplary method includes receiving an integrated circuit (IC) design layout and generating an exposure map based on the IC design layout. The IC design layout includes a target pattern to be formed on a workpiece, and the exposure map includes an exposure grid divided into dark pixels and bright pixels that combine to form the target pattern. The method further includes adjusting the exposure map to increase exposure dosage at edges of the target pattern. In some implementations, the adjusting includes locating an edge portion of the target pattern in the exposure map, where the edge portion has a corresponding bright pixel, and assigning exposure energy from at least one dark pixel to the corresponding bright pixel, thereby generating a modified exposure map.

Abstract: A method includes establishing a simulation process for simulating fabrication of a structure on a wafer. The simulation process includes multiple simulation steps for simulating multiple wafer fabrication steps respectively, and further includes a step of testing the structure that produces a result representing quality of the structure. Each of the simulation steps has a respective adjustable process parameter. The method further includes specifying a respective workable range for each process parameter and running the simulation process in iterations using a wafer process simulator until the result becomes optimal. During the running of the simulation process, every two consecutive iterations either adjust two different process parameters within their workable ranges or adjust a same process parameter at opposite directions within its workable range.

Abstract: A pattern modification method and a patterning process are provided. The method includes extracting a first pattern and a second pattern to be respectively transferred to a first target portion and a second target portion of a resist layer. The method also includes obtaining regional information of the first target portion and the second target portion. The method includes determining a first desired focus position for transferring the first pattern based on the regional information. In addition, the method includes determining a second desired focus position for transferring the second pattern based on the regional information. The method includes modifying one or both of the first pattern and the second pattern. As a result, focus positions of the first pattern and the second pattern are shifted to be substantially and respectively positioned at the first desired focus position and the second desired focus position during an exposure operation.

Abstract: The present disclosure provides a method of patterning a target material layer over a semiconductor substrate. The method includes steps of forming a spacer feature over the target material layer using a first sub-layout and performing a photolithographic patterning process using a second sub-layout to form a first feature. A portion of the first feature extends over the spacer feature. The method further includes steps of removing the portion of the first feature extending over the spacer feature and removing the spacer feature. Other methods and associated patterned semiconductor wafers are also provided herein.

Abstract: The present disclosure provides one embodiment of a method that includes slicing a first sub-polygon out of the pattern layout and writing the first sub-polygon onto the substrate using a beam with a first beam setting that is associated with the first sub-polygon. The method additional includes slicing a second sub-polygon out of the remaining pattern layout that does not include the first sub-polygon. The second sub-polygon interfaces with the first sub-polygon on at least one edge. Also, the method includes, without turning off the beam after writing the first sub-polygon onto the substrate, writing the second sub-polygon onto the substrate with a second beam setting that is associated with the second sub-polygon.