Abstract: A method for forming a semiconductor device structure is provided. The method includes forming a first layer over a substrate. The first layer has a trench. The method includes forming first spacers over inner walls of the trench. The method includes removing a portion of the first spacers. The method includes forming a filling layer into the trench to cover the first spacers. The filling layer and the first spacers together form a strip structure. The method includes removing the first layer. The method includes forming second spacers over two opposite first sidewalls of the strip structure.

Abstract: In a method of forming a pattern, a photo resist layer is formed over an underlying layer, the photo resist layer is exposed to an actinic radiation carrying pattern information, the exposed photo resist layer is developed to form a developed resist pattern, a directional etching operation is applied to the developed resist pattern to form a trimmed resist pattern, and the underlying layer is patterned using the trimmed resist pattern as an etching mask.

Abstract: A method of manufacturing a semiconductor device includes dividing a number of dies along an x axis in a die matrix in each exposure field in an exposure field matrix delineated on the semiconductor substrate, wherein the x axis is parallel to one edge of a smallest rectangle enclosing the exposure field matrix. A number of dies is divided along a y axis in the die matrix, wherein the y axis is perpendicular to the x axis. Sequences SNx0, SNx1, SNx, SNxr, SNy0, SNy1, SNy, and SNyr are formed. p*(Nbx+1)?2 stepping operations are performed in a third direction and first sequence exposure/stepping/exposure operations and second sequence exposure/stepping/exposure operations are performed alternately between any two adjacent stepping operations as well as before a first stepping operation and after a last stepping operation. A distance of each stepping operation in order follows the sequence SNx.

Abstract: A method of performing a lithography process includes providing a test pattern. The test pattern includes a first set of lines arranged at a first pitch, a second set of lines arranged at the first pitch, and further includes at least one reference line between the first set of lines and the second set of lines. The test pattern is exposed with a radiation source providing an asymmetric, monopole illumination profile to form a test pattern structure on a substrate. The test pattern structure is then measured and a measured distance correlated to an offset of a lithography parameter. A lithography process is adjusted based on the offset of the lithography parameter.

Abstract: An integrated circuit (IC) method is provided. The method includes building a mask model to simulate an aerial mask image of a mask, and a compound lithography computational (CLC) model to simulate a wafer pattern; calibrating the mask model using a measured aerial mask image of the mask; calibrating the CLC model using measured wafer data and the calibrated mask model; performing an optical proximity correction (OPC) process to a mask pattern using the calibrated CLC model, thereby generating a corrected mask pattern for mask fabrication. Alternatively, the method includes measuring a mask image of a mask optically projected on a wafer with an instrument; calibrating a mask model using the measured mask image; calibrating a CLC model using measured wafer data and the calibrated mask model; and performing an OPC process to a mask pattern using the calibrated CLC model, thereby generating a corrected mask pattern for mask fabrication.

Abstract: Semiconductor structures and methods for forming a semiconductor structure are provided. An active semiconductor region is disposed in a substrate. A gate is formed over the substrate. Source and drain regions of a transistor are formed in the active semiconductor region on opposite sides of the gate. The drain region has a first width, and the source region has a second width that is not equal to the first width.

Abstract: Methods are disclosed herein for patterning integrated circuit devices, such as fin-like field effect transistor devices. An exemplary method includes forming a material layer that includes an array of fin features, and performing a fin cut process to remove a subset of the fin features. The fin cut process includes exposing the subset of fin features using a cut pattern and removing the exposed subset of the fin features. The cut pattern partially exposes at least one fin feature of the subset of fin features. In implementations where the fin cut process is a fin cut first process, the material layer is a mandrel layer and the fin features are mandrels. In implementations where the fin cut process is a fin cut last process, the material layer is a substrate (or material layer thereof), and the fin features are fins defined in the substrate (or material layer thereof).

Abstract: A method is disclosed, including the following operations: arranging a first gate structure extending continuously above a first active region and a second active region of a substrate; arranging a first separation spacer disposed on the first gate structure to isolate an electronic signal transmitted through a first gate via and a second gate via that are disposed on the first gate structure, in which the first gate via and the second gate via are arranged above the first active region and the second active region respectively; and arranging a first local interconnect between the first active region and the second active region, in which the first local interconnect is electrically coupled to a first contact disposed on the first active region and a second contact disposed on the second active region.

Abstract: A method of manufacturing a semiconductor device includes depositing a first material on a substrate, depositing on the substrate a second material that has an etch selectivity different from an etch selectively of the first material, depositing a spacer material on the first and second material, and etching the substrate using the spacer material as an etch mask to form a fin under the first material and a fin under the second material.

Abstract: A method for mask data synthesis and mask making includes calibrating an optical proximity correction (OPC) model by adjusting a plurality of parameters including a first parameter and a second parameter, wherein the first parameter indicates a long-range effect caused by an electron-beam lithography tool for making a mask used to manufacture a structure, and the second parameter indicates a geometric feature of a structure or a manufacturing process to make the structure, generating a device layout, calculating a first grid pattern density map of the device layout, generating a long-range correction map, at least based on the calibrated OPC model and the first grid pattern density map of the device layout, and performing an OPC to generate a corrected mask layout, at least based on the generated long-range correction map and the calibrated OPC model.

Abstract: A four signal line unit cell is formed on a substrate using a combination of an extreme ultraviolet photolithography process and one or more self aligned deposition processes. The photolithography process and the self aligned deposition processes result in spacers on a hard mask above the substrate. The spacers define a pattern of signal lines to be formed on the substrate for a unit cell. The photolithography process and self aligned deposition processes result in signal lines having a critical dimension much smaller than features that can be defined by the extreme ultraviolet photolithography process.

Abstract: Examples of an integrated circuit a having an advanced two-dimensional (2D) metal connection with metal cut and methods of fabricating the same are provided. An example method for fabricating a conductive interconnection layer of an integrated circuit may include: patterning a conductive connector portion on the conductive interconnection layer of the integrated circuit using extreme ultraviolet (EUV) lithography, wherein the conductive connector portion is patterned to extend across multiple semiconductor structures in a different layer of the integrated circuit; and cutting the conductive connector portion into a plurality of conductive connector sections, wherein the conductive connector portion is cut by removing conductive material from the metal connector portion at one or more locations between the semiconductor structures.

Abstract: A method includes forming a material layer over a substrate, forming a first hard mask (HM) layer over the material layer, forming a first trench, along a first direction, in the first HM layer. The method also includes forming first spacers along sidewalls of the first trench, forming a second trench in the first HM layer parallel to the first trench, by using the first spacers to guard the first trench. The method also includes etching the material layer through the first trench and the second trench, removing the first HM layer and the first spacers, forming a second HM layer over the material layer, forming a third trench in the second HM layer. The third trench extends along a second direction that is perpendicular to the first direction and overlaps with the first trench. The method also includes etching the material layer through the third trench.

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: A semiconductor device includes a first gate structure, a second gate structure, a first source/drain structure and a second source/drain structure. The first gate structure includes a first gate electrode and a first cap insulating layer disposed on the first gate electrode. The second gate structure includes a second gate electrode and a first conductive contact layer disposed on the first gate electrode. The first source/drain structure includes a first source/drain conductive layer and a second cap insulating layer disposed over the first source/drain conductive layer. The second source/drain structure includes a second source/drain conductive layer and a second conductive contact layer disposed over the second source/drain conductive layer.

Abstract: The present disclosure provides a method for forming interconnect structures. The method includes providing a semiconductor structure including a substrate and a conductive feature formed in a top portion of the substrate; depositing a resist layer over the substrate, wherein the resist layer has an exposure threshold; providing a radiation with an incident exposure dose to the resist layer, wherein the incident exposure dose is configured to be less than the exposure threshold of the resist layer while a sum of the incident exposure dose and a reflected exposure dose from a top surface of the conductive feature is larger than the exposure threshold of the resist layer, thereby forming a latent pattern above the conductive feature; and developing the resist layer to form a patterned resist layer.

Abstract: Implementations of the present disclosure provide coloring methods that sort and pre-color nodes of G0-linked networks in a multiple-patterning technology (MPT)-compliant layout design by coordinate. In one embodiment, a method includes identifying target networks in a circuit layout, each target network having two or more linked nodes representing circuit patterns, and each target network being presented in an imaginary X-Y coordinate plane, assigning a first feature to a first node in each target network, the first node is determined using a coordinate-based method, and assigning the first feature and a second feature to remaining nodes in each target network in an alternating manner so that any two immediately adjacent linked nodes in each target network have different features.

Abstract: A method for taking heat away from the photomask includes driving a working fluid to flow between a photomask and a fluid retaining structure and through a first slit of the fluid retaining structure, such that a boundary of the working fluid is confined between the photomask and the fluid retaining structure; and generating a light to irradiate the photomask through a light transmission region of the fluid retaining structure.

Abstract: In a method of forming a groove pattern extending in a first axis in an underlying layer over a semiconductor substrate, a first opening is formed in the underlying layer, and the first opening is extended in the first axis by directional etching to form the groove pattern.

Abstract: A self aligned via and a method for fabricated a semiconductor device using a double-trench constrained self alignment process to form the via. The method includes forming a first trench and depositing a first metal into the first trench. Afterwards, the process includes depositing a dielectric layer over the first metal such that a top surface of the dielectric layer is at substantially the same level as the top surface of the first trench. Next, a second trench is formed and a via is formed by etching the portion of the dielectric layer exposed by the overlapping region between the first trench and the second trench. The via exposes a portion of the first metal and a second metal is deposited into the second trench such that the second metal is electrically coupled to the first metal.