Abstract: A method for obtaining a layout design for an existing integrated circuit, in which, an integrated circuit die is polished with a tilt angle to form an inclined polished surface and one or more images of the inclined polished surface are obtained. The images may be overlapped directly, or the image or the images may be utilized to provide information to obtain a layout design comprising at least one repeating unit structure of the layout structure.

Abstract: A method of via formation in a semiconductor device includes the following steps of providing a photoresist with a photoresist pattern defining an opening of a via, wherein the photoresist comprising a thermally cross-linking material is disposed on a structure layer; dry-etching the structure layer to a first depth through the opening; baking the thermally cross-linking material to reduce the opening; and dry-etching the structure layer to a second depth through the reduced opening, wherein the second depth is greater than the first depth.

Abstract: A method of forming conductive pattern is provided. A seeding layer is formed on an underlayer. By using an energy ray, an irradiation treatment is performed on a portion of a surface of the seeding layer. The seeding layer thus includes a plurality of irradiated regions and a plurality of unirradiated regions. A conversion treatment is performed on the irradiated regions of the seeding layer. A selective growth process is performed, so as to form a conductive pattern on each unirradiated region of the seeding layer. The irradiated regions of the seeding layer are removed, so that the conductive patterns are insulated from each other.

Abstract: A circuit structure with a capacitor or a resistor includes a semiconductor substrate, a first conductive region positioned in the semiconductor substrate, a plurality of second conductive regions and third conductive regions positioned in the first conductive region, a first depletion region positioned between the first conductive region and the third conductive region, a second depletion region positioned between the second conductive region and the third conductive region, and a plurality of separating regions positioned in the first conductive region, configured to separate the second and the third conductive regions. In operation, a first voltage is applied to the separating region to control the capacitance or the resistance of the circuit structure. A second voltage is applied to the first conductive region and a third voltage is applied to the second conductive region to measure the capacitance and the resistance of the circuit structure.

Abstract: A circuit structure including a semiconductor substrate having a depression; a first insulating layer positioned on the surface of the depression; a bottom conductor positioned in a bottom portion of the depression, wherein the bottom conductor is connected to an external bias through a plurality of longer vertical contact plugs; an upper conductor positioned in an upper portion of the depression, wherein the upper conductor is connected to a plurality of shorter vertical contact plugs, and a top surface of the upper conductor is higher than a depression-bearing surface of the semiconductor substrate; and a second insulating layer positioned between the bottom conductor and the upper conductor.

Abstract: A method for fabricating a fin-shaped semiconductor structure is provided, including: providing a semiconductor substrate with a semiconductor island and a dielectric layer formed thereover; forming a mask layer over the semiconductor island and the dielectric layer; forming an opening in the mask layer, exposing a top surface of the semiconductor island and portions of the dielectric layer adjacent to the semiconductor island; performing an etching process, simultaneously etching portions of the mask layer, and portions of the semiconductor island and the dielectric layer exposed by the opening; and removing the mask layer and the dielectric layer, leaving an etched semiconductor island with curved top surfaces and various thicknesses over the semiconductor substrate.

Abstract: The present invention in a first aspect proposes a semiconductor structure with a crack stop structure. The semiconductor structure includes a matrix, an integrated circuit and a scribe line. The matrix includes a scribe line region and a circuit region. The integrated circuit is disposed within the circuit region. The scribe line is disposed within the scribe line region and includes a crack stop trench which is disposed in the matrix and adjacent to the circuit region. The crack stop trench is parallel with one side of the circuit region and filled with a composite material in the form of a grid to form a crack stop structure.

Abstract: The present invention provides a method of reducing microloading effect by using a photoresist layer as a buffer. The method includes: providing a substrate defined with a dense region and an isolated region. Then, a dense feature pattern and an isolated feature pattern are formed on the dense region and the isolated region respectively. After that, a photoresist layer is formed to cover the isolated region. Finally, the substrate and the photoresist layer are etched by taking the dense feature pattern and the isolated feature pattern as a mask.

Abstract: A method for forming a contact of a semiconductor device with reduced step height is disclosed, comprising forming a plurality of gates, forming a buffer layer on each of the gates, forming an insulating layer to fill spaces between the gates, forming strip-shaped photoresist patterns which cross the gates, etching the insulating layer to form first openings using a self-aligning process with the gates and the strip-shaped photoresist patterns as a mask, forming a conductive contact layer to fill the first openings, performing a first chemical mechanical polish (CMP) process to the conductive contact layer, removing the buffer layer, and forming a second chemical mechanical polish (CMP) process to the conductive contact layer.

Abstract: A method for forming an opening in a semiconductor device is provided, including: providing a semiconductor substrate with a silicon oxide layer, a polysilicon layer and a silicon nitride layer sequentially formed thereover; patterning the silicon nitride layer, forming a first opening in the silicon nitride layer, wherein the first opening exposes a top surface of the polysilicon layer; performing a first etching process, using gasous etchants including hydrogen bromide (HBr), oxygen (O2), and fluorocarbons (CxFy), forming a second opening in the polysilicon layer, wherein a sidewall of the polysilicon layer adjacent to the second opening is substantially perpendicular to a top surface of the silicon oxide layer, wherein x is between 1-5 and y is between 2-8; removing the silicon nitride layer; and performing a second etching process, forming a third opening in the silicon oxide layer exposed by the second opening.

Abstract: A process of forming a slit in a substrate is provided. A mask layer is formed on a substrate, wherein the mask layer does not include carbon. An etching process is performed to be substrate by using the mask layer as a mask, so as to form a slit in the substrate. The etching gas includes Cl2, CF4 and CHF3, a molar ratio of CF4 to CHF3 is about 0.5-0.8, and a molar ratio of F to Cl is about 0.4-0.8, for example. Further, the step of performing the etching process simultaneously removes the mask layer.

Abstract: A method of inspecting a memory cell is provided, including: providing a semiconductor substrate with a capacitor formed therein and a transistor formed thereon, wherein the transistor is electrically connected to the capacitor; inspecting a size of a top surface of the capacitor and a pitch between the capacitor and the transistor electrically connected thereto by an optical measuring system, thereby obtaining a first measurement data and a second measurement data; and comparing the first and second measurement data with designed specifications of the capacitor and transistor, thereby determining functionality of the memory cell comprising the capacitor and the transistor.

Abstract: A semiconductor process is provided. A mask layer is formed on a substrate and has a first opening exposing a portion of the substrate. Using the mask layer as a mask, a dry etching process is performed on the substrate to form a second opening therein. The second opening has a bottom portion and a side wall extending upwards and outwards from the bottom portion, wherein the bottom portion is exposed by the first opening and the side wall is covered by the mask layer. Using the mask layer as a mask, a vertical ion implantation process is performed on the bottom portion. A conversion process is performed, so as to form converting layers on the side wall and the bottom portion of the second opening, wherein a thickness of the converting layer on the side wall is larger than a thickness of the converting layer on the bottom portion.

Abstract: A semiconductor process is provided. A substrate is provided, gates each including a silicon layer, a silicide layer and a cap layer are formed thereon, and doped regions are formed at two sides of each gate. An insulating layer is formed to cover a memory region and a periphery region. First contact holes are formed in the insulating layer in the memory region, and each first contact hole is disposed between the two adjacent gates and exposes the doped region. A contact plug is formed in each first contact hole to electrically connect the doped region. A patterned mask layer is formed on the substrate to cover the memory region and expose a portion of the periphery region. Using the patterned mask layer as a mask, second and third contact holes are formed in the insulating layer in the periphery region, to expose the silicide layer and the doped region.

Abstract: A method of reducing striation on a sidewall of a recess is provided. The method includes the steps of providing a substrate covered with a photoresist layer. Then, the photoresist layer is etched to form a patterned photoresist layer. Later, a repairing process is performed by treating the patterned photoresist layer with a repairing gas which is selected from the group consisting of CF4, HBr, O2 and He. Next, the substrate is etched by taking the patterned photoresist layer as a mask after the repairing process. Finally, the patterned photoresist layer is removed.

Abstract: The present invention provides a method of reducing microloading effect by using a photoresist layer as a buffer. The method includes: providing a substrate defined with a dense region and an isolated region. Then, a dense feature pattern and an isolated feature pattern are formed on the dense region and the isolated region respectively. After that, a photoresist layer is formed to cover the isolated region. Finally, the substrate and the photoresist layer are etched by taking the dense feature pattern and the isolated feature pattern as a mask.

Abstract: The disclosure provides a method for wafer implantation including the following steps: providing a wafer, wherein the wafer comprises a central circular portion, and a peripheral annular portion adjacent to a edge of the wafer, and wherein the central circular portion and the peripheral annular portion are concentric; and implanting ion beams into the wafer, wherein the central circular portion has a first average implantation dose and the peripheral annular portion has a second average implantation dose, and the first average implantation dose and the second first average implantation dose are different.

Abstract: A slit recess channel gate is further provided. The slit recess channel gate includes a substrate, a gate dielectric layer, a first conductive layer and a second conductive layer. The substrate has a first trench. The gate dielectric layer is disposed on a surface of the first trench and the first conductive layer is embedded in the first trench. The second conductive layer is disposed on the first conductive layer and aligned with the first conductive layer above the main surface, wherein a bottom surface area of the second conductive layer is substantially smaller than a top surface area of the second conductive layer. The present invention also provides a method of forming the slit recess channel gate.

Abstract: A test layout structure includes a substrate, a first oxide region of a first height, a second oxide region of a second height, a plurality of border regions, and a test layout pattern. The first oxide region is disposed on the substrate. The second oxide region is also disposed on the substrate and adjacent to the first oxide region. The first height is substantially different from the second height. A plurality of border regions are disposed between the first oxide region and the second oxide region. The test layout pattern includes a plurality of individual sections. A test region is disposed between two of the adjacent individual sections which are parallel to each other.

Abstract: A method of via formation in a semiconductor device includes the following steps of providing a photoresist with a photoresist pattern defining an opening of a via, wherein the photoresist comprising a thermally cross-linking material is disposed on a structure layer; dry-etching the structure layer to a first depth through the opening; baking the thermally cross-linking material to reduce the opening; and dry-etching the structure layer to a second depth through the reduced opening, wherein the second depth is greater than the first depth.