Abstract: A semiconductor manufacturing method that includes depositing a first layer over a substrate, providing a layer of hardmask over the first layer, patterning and defining the hardmask layer to form at least two hardmask structures, wherein each hardmask structure includes at least one substantially vertical sidewall and one substantially horizontal top, and wherein the hardmask structures are separated by a first space, depositing a photo-insensitive material over the at least two hardmask structures and the first layer, wherein an amount of the photo-insensitive material deposited on the top of the hardmask structures is substantially greater than an amount of the photo-insensitive material deposited on the at least one sidewall of the hardmask structures, wherein the hardmask structures with the photo-insensitive layer on the sidewalls thereof are separated by a second space, and wherein the first space is greater than the second space.

Abstract: A semiconductor manufacturing method that includes providing a substrate, providing a layer of material over the substrate, providing a layer of photoresist over the material layer, patterning and defining the photoresist layer, depositing a layer of polymer over the patterned and defined photoresist layer, wherein the layer of polymer is conformal and photo-insensitive, and etching the layer of polymer and the layer of material.

Abstract: A method of reducing pattern pitch is provided. A material layer, a hard mask layer and a patterned photoresist layer are sequentially formed over a substrate. Using the patterned photoresist layer as etching mask, the hard mask layer is etched. Due to the trenching effect, a residual hard mask layer remains in an exposed region exposed by the photoresist layer and micro-trenches are formed at the edges of the residual hard mask layer. Thereafter, using the residual hard mask layer as etching mask to pattern the material layer. Finally, the patterned photoresist layer and the hard mask layer are removed. In the invention, the trenching effect is utilized when etching the hard mask layer. A portion of the hard mask layer remains, and the micro-trenches are formed in the hard mask layer. After the micro-trenches are transferred to the material layer, the pattern pitch can be reduced.

Abstract: A semiconductor manufacturing method that includes defining a substrate, depositing a polysilicon layer over the substrate, depositing a layer of photoresist over the polysilicon layer, patterning and defining the photoresist layer, depositing a layer of inorganic material over the patterned and defined photoresist layer, wherein the layer of inorganic material is conformal and photo-insensitive, and anisotropic etching the layer of inorganic material and the layer of semiconductor material.

Abstract: A method of reducing pattern pitch is provided. A material layer, a hard mask layer and a patterned photoresist layer are sequentially formed over a substrate. Using the patterned photoresist layer as etching mask, the hard mask layer is etched. Due to the trenching effect, a residual hard mask layer remains in an exposed region exposed by the photoresist layer and micro-trenches are formed at the edges of the residual hard mask layer. Thereafter, using the residual hard mask layer as etching mask to pattern the material layer. Finally, the patterned photoresist layer and the hard mask layer are removed. In the invention, the trenching effect is utilized when etching the hard mask layer. A portion of the hard mask layer remains, and the micro-trenches are formed in the hard mask layer. After the micro-trenches are transferred to the material layer, the pattern pitch can be reduced.

Abstract: The present invention discloses a semiconductor device having a rounding profile structure for reducing the step profile and the manufacturing processing stress and a method for rounding the corner of the membrane element in a semiconductor device. In the present invention, a membrane is deposited on a semiconductor substrate, then after a photo-resist pattern transferring step, dry etching step, and photo-resist removing step, a patterned membrane element is formed thereon. Then, a sacrificing layer is formed conformally overlaying the patterned membrane element, wherein the sacrificing layer is step height according to the patterned membrane element. Following, an etching back step is performed to etch the sacrificing layer by selectivity etching to form a rounding profile of the coroner of the membrane element. Last, the residual sacrificing layer is removed.

Abstract: The present invention generally relates to a dual damascene processing method using a silicon rich oxide (SRO) layer thereof and its structure. In the dual damascene process, a first dielectric layer, an etching stop layer, such as a silicon rich oxide layer, and a second dielectric layer are sequentially formed on a semiconductor substrate, which is provided with metal connections therein. Then, the present invention utilizes photolithography and etching technique to obtain a dual damascene structure profile having a trench and a via hole. The present invention uses the silicon rich oxide layer as the etching stop layer so as the present invention can achieve a better trench microloading and better bottom profile. Beside, the present invention does not increase the dielectric constant index (K) of the inter metal dielectric (IMD).

Abstract: A semiconductor manufacturing method that includes defining a substrate, depositing a polysilicon layer over the substrate, depositing a layer of photoresist over the polysilicon layer, patterning and defining the photoresist layer, depositing a layer of inorganic material over the patterned and defined photoresist layer, wherein the layer of inorganic material is conformal and photo-insensitive, and anisotropic etching the layer of inorganic material and the layer of semiconductor material.

Abstract: A semiconductor manufacturing method that includes defining a substrate, depositing a polysilicon layer over the substrate, depositing a layer of photoresist over the polysilicon layer, patterning and defining the photoresist layer, depositing a layer of inorganic material over the patterned and defined photoresist layer, wherein the layer of inorganic material is conformal and photo-insensitive, and anisotropic etching the layer of inorganic material and the layer of semiconductor material.

Abstract: A semiconductor manufacturing method that includes depositing a first layer over a substrate, providing a layer of hardmask over the first layer, patterning and defining the hardmask layer to form at least two hardmask structures, wherein each hardmask structure includes at least one substantially vertical sidewall and one substantially horizontal top, and wherein the hardmask structures are separated by a first space, depositing a photo-insensitive material over the at least two hardmask structures and the first layer, wherein an amount of the photo-insensitive material deposited on the top of the hardmask structures is substantially greater than an amount of the photo-insensitive material deposited on the at least one sidewall of the hardmask structures, wherein the hardmask structures with the photo-insensitive layer on the sidewalls thereof are separated by a second space, and wherein the first space is greater than the second space.

Abstract: A method for manufacturing a photomask is provided. A transparent substrate is provided and a mask layer is formed thereon. A resist layer is formed on the mask layer and then patterned and defined to define a critical dimension of the photomask. A third layer is deposited over the patterned and defined resist layer to decrease the critical dimension of the photomask. And the third layer and the mask layer are etched afterwards.

Abstract: A semiconductor manufacturing method that includes providing a substrate, providing a layer of semiconductor material over the substrate, providing a layer of photoresist over the semiconductor material layer, patterning and defining the photoresist layer, depositing a layer of polymer over the patterned and defined photoresist layer, wherein the layer of polymer is conformal and photo-insensitive, and etching the layer of polymer and the layer of semiconductor material.

Abstract: The present invention generally relates to a dual damascene processing method using a silicon rich oxide (SRO) layer thereof and its structure. In the dual damascene process, a first dielectric layer, an etching stop layer, such as a silicon rich oxide layer, and a second dielectric layer are sequentially formed on a semiconductor substrate, which is provided with metal connections therein. Then, the present invention utilizes photolithography and etching technique to obtain a dual damascene structure profile having a trench and a via hole. The present invention uses the silicon rich oxide layer as the etching stop layer so as the present invention can achieve a better trench microloading and better bottom profile. Beside, the present invention does not increase the dielectric constant index (K) of the inter metal dielectric (IMD).

Abstract: An operating method of a semiconductor etcher includes three steps. The first step is to provide a first power for shortening a warm-up time of the etcher. The second step is to provide a second power, which is lower than the first power, to perform an etching process. The third step is to provide a third power, which is between the first and second power, for cleaning the etcher.

Abstract: The present invention is to utilize chemical dry etching technique to form a rounded corner in a shallow trench isolation process. After finishing the etching of the shallow trench, the present invention utilizes an isotropic etching step, which is a chemical dry etching step of a high silicon nitride to silicon etching selectivity, to pullback the silicon nitride layer to expose a silicon top corner. Then, the present invention utilizes an isotropic etching step, which is a chemical dry etching step of a high silicon to silicon nitride etching selectivity, to make the corner rounded to obtain a rounded corner of the shallow trench isolation structure. The present invention can avoid the formation of wrap rounding of the corner and prevent the formation of the short circuit or extraordinary electric behavior between adjacent devices and supply for performing following processes.

Abstract: An apparatus for cleaning a semiconductor wafer is disclosed to substantially improve the efficiency of the cleaning process, and reduce the quantity of cleaning solvent used. The apparatus includes a rotating table for supporting the wafer, a rotation device to rotate the rotation table, a movable or stationary curved-slab for scrubbing the surface of the wafer efficiently, a cleaning nozzle for applying a cleaning solvent or stripper on the surface of the wafer, and a resistance wall for preventing the cleaning solvent spun out from the wafer to pollute the cleaning room.

Abstract: A semiconductor manufacturing method that includes defining a substrate, depositing a polysilicon layer over the substrate, depositing a layer of photoresist over the polysilicon layer, patterning and defining the photoresist layer, depositing a layer of inorganic material over the patterned and defined photoresist layer, wherein the layer of inorganic material is conformal and photo-insensitive, and anisotropic etching the layer of inorganic material and the layer of semiconductor material.

Abstract: The present invention generally relates to provide a fabrication method for forming a rounded corner of a contact window or a via by using a two-step light etching technique. In the present invention, after the etching process to form the contact window or the via, an object of the invention is to utilize oxygen plasma and fluorocarbon plasma of the two-step light etching technique to produce the rounded corner of the window or via so as this rounded opening profile of the contact window or the via can supply for following metal-filling processes.

Abstract: This invention provides a method for chamber conditioning with deposition mode. The method includes performing organic gas introduced constantly into a chamber, wherein said organic gas comprises halogen. Adhesive polymers are formed from said organic gas and particles in the chamber, and deposited onto the wall of the chamber to form heavy polymers subsequently. It is necessary to make a similar chamber condition for manufacturing every batch of wafer. In other words, the development of a non-ignored pollution problem, which is increasing with batches of the manufacturing of wafers will not occur. By using said method of deposition mode, it is speedily and easy to decrease the amount of particles in the chamber for the requirement for wafer manufacturing.

Abstract: A method of etching a metallic layer having an anti-reflection layer thereon. The method includes performing a first etching operation using a fixed set of processing parameters to etch the anti-reflection layer and remove a specified thickness of the metallic layer. Thereafter, a second etching operation is conducted to etch the remaining metallic layer.