Abstract: A trench MOS structure is provided. The trench MOS structure includes a substrate, an epitaxial layer, a trench, a gate isolation, a trench gate, a guard ring and a reinforcement structure within the guard ring. The substrate has a first conductivity type, a first side and a second side opposite to the first side. The epitaxial layer has the first conductivity type and is disposed on the first side. The trench is disposed in the epitaxial layer. The gate isolation covers the inner wall of the trench. The trench gate is disposed in the trench and has the first conductivity type. The guard ring has a second conductivity type and is disposed within the epitaxial layer. The reinforcement structure has an electrically insulating material and is disposed within the guard ring.

Abstract: A chemical mechanical polishing (CMP) system includes a wafer polishing unit producing a used slurry; a slurry treatment system for receiving and treating the used slurry to thereby produce an extracted basic solution; and a post-CMP cleaning unit utilizing the extracted basic solution to wash a polished wafer surface. The post-CMP cleaning unit includes a plurality of rollers for supporting and rotating a wafer, a brush for scrubbing the wafer, and a spray bar disposed in proximity to the brush for spraying the extracted basic solution onto the polished wafer surface.

Abstract: An optical lens is provided in the present invention. The optical lens includes a first curved surface and an annular mask component on and in direct contact with the first curved surface, wherein the annular mask component shields a peripheral annular region of the optical lens from entry of light. The present invention further provides an optical microscope system using the same.

Abstract: The protuberant structure of the present invention includes a substrate and a protrusion disposed on the substrate. The protrusion has a top side, a bottom side and a tapered side wall disposed between the top side and the bottom side. The top side has an extremely small top width which is not greater than 32 nm.

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 etching trenches in a semiconductor substrate. A patterned hard mask is formed over a semiconductor substrate. Using the patterned hard mask as an etching mask, a plasma etching process is then carried out to etch trenches into the semiconductor substrate not covered by the patterned hard mask, wherein the plasma etching process employs a fluorocarbon-free plasma etching chemistry and is performed under a plasma pulse output mode.

Abstract: A method for decapsulating an integrated circuit package without the need of using a mask during the decapsulation process is disclosed. First, a package is provided. The package includes at least a circuit element and a molding compound enclosing the circuit. Second, a caustic solution is simultaneously provided. The caustic solution is capable of etching the molding compound and intermittently contacts a pre-selected area of the molding compound to etch the molding compound. As a consequence, the caustic solution removes the molding compound in the pre-selected area so the circuit element in the package is substantially exposed.

Abstract: A MOS test structure is disclosed. A scribe line region is disposed on a substrate which has a first side and a second side opposite to the first side. An epitaxial layer is disposed on the first side, the doping well is disposed on the epitaxial layer and the doping region is disposed on the doping well. A trench gate of a first depth is disposed in the doping region, in the doping well and in the scribe line region. A conductive material fills the test via which has a second depth and an isolation covering the inner wall of the test via and is disposed in the doping region, in the doping well, in the epitaxial layer and in the scribe line region, to electrically connect to the epitaxial layer so that the test via is capable of testing the epitaxial layer and the substrate together.

Abstract: A semiconductor process is provided. A substrate is provided in an etching apparatus, wherein first conductive patterns, a barrier layer and a patterned insulating layer are formed thereon. The first openings are formed between the first conductive patterns, the barrier layer covers surfaces of the first conductive patterns and the first openings, and the patterned insulating layer is formed on the first conductive patterns and has a plurality of second openings. The second openings expose the barrier layer on top corners of the first conductive patterns. Polymer layers are formed on the barrier layer, wherein a thickness of the polymer layer on the top corners of the first conductive pattern is larger than a thickness of the polymer layer on bottom portions of the first openings. An etching process is performed to remove the polymer layer and the barrier layer disposed on the bottom portions of the first openings.

Abstract: A manufacturing method of a device is provided. In the manufacturing method, a substrate is provided. The substrate has a plurality of patterns and a plurality of openings formed thereon, and the openings are located among the patterns. A first liquid supporting layer is formed on the patterns, and the openings are filled with the first liquid supporting layer. The first liquid supporting layer is transformed into a first solid supporting layer. The first solid supporting layer includes a plurality of supporting elements formed in the openings, and the supporting elements are formed among the patterns. A treatment process is performed on the patterns. The first solid supporting layer that includes the supporting elements is transformed into a second liquid supporting layer. The second liquid supporting layer is removed.

Abstract: A method for increasing adhesion between polysilazane and silicon nitride is disclosed, comprising, providing a substrate comprising a trench, forming a silicon nitride liner layer on a bottom surface and a sidewall of the trench, performing a treating process to the silicon nitride liner layer for producing a hydrophilic surface with OH groups that can increase adhesion between the silicon nitride liner layer and a subsequently formed polysilazane coating layer, and forming a polysilazane coating layer into the trench and on the silicon nitride liner layer.

Abstract: An integrated circuit structure including a copper-aluminum interconnect with a CuSiN layer and a method for fabricating the same are provided. The method for fabricating an integrated circuit structure including a copper-aluminum interconnect according to the present invention comprises the steps of providing a copper (Cu) layer; forming a barrier layer including a CuSiN layer on the copper layer; forming a wetting layer on the barrier layer; and forming an aluminum (Al) layer on the wetting layer.

Abstract: A method for fabricating a gate dielectric layer comprises the steps of: forming a dielectric layer on a semiconductor substrate; performing a nitrogen treating process to form a nitride layer on the dielectric layer; and performing a thermal treating process at 1150-1400° C. for a period of 400-800 milliseconds, to form a gate dielectric layer. A step of forming a gate layer on the gate dielectric layer may be performed to form a gate structure.

Abstract: A method of forming a buried bit line is provided. A substrate is provided and a line-shaped trench region is defined in the substrate. A line-shaped trench is formed in the line-shaped trench region of the substrate. The line-shaped trench includes a sidewall surface and a bottom surface. Then, the bottom surface of the line-shaped trench is widened to form a curved bottom surface. Next, a doping area is formed in the substrate adjacent to the curved bottom surface. Lastly, a buried conductive layer is formed on the doping area such that the doping area and the buried conductive layer together constitute the buried bit line.

Abstract: An integrated circuit structure including a copper-aluminum interconnect with a barrier layer including a titanium nitride layer and a method for fabricating the same are disclosed. The method for fabricating an integrated circuit structure including a copper-aluminum interconnect according to the present invention comprises the steps of providing a copper (Cu) layer; forming a barrier layer connected to the copper layer, wherein the barrier layer comprises a first layer including a tantalum layer and a tantalum nitride layer and a second layer including a titanium nitride layer, the first layer contacts the copper layer and is disposed between the copper layer and the second layer, and the barrier layer has a recess correspondingly above the copper layer; and forming an aluminum (Al) layer disposed in the recess.

Abstract: A method for forming a trench isolation is disclosed, comprising, providing a substrate comprising a trench, forming a polysilicon layer in the trench, and subjecting the substrate to a treating process to convert the polysilicon layer to an isolating layer, wherein the treating process is fine tuned for the isolating layer on opposite sidewalls of the trench to expand to contact with each other so that the isolating layer fills the trench.

Abstract: A method for fabricating a gate dielectric layer comprises the steps of: forming a dielectric layer on a semiconductor substrate; performing a nitrogen treating process to form a nitride layer on the dielectric layer; performing an oxygen treating process to implant oxygen into the nitride layer; and performing a thermal treating process to form a gate dielectric layer. A step of forming a gate layer on the gate dielectric layer may be performed to form a gate structure.

Abstract: A method of oxidizing polysilazane is disclosed, comprising providing a substrate, comprising a trench, forming a polysilazane layer in the trench, and treating the polysilazane layer in an acid containing solution applied with mega-sonic waves to oxidize the polysilazane layer, wherein the acid containing solution comprises phosphoric acid, sulfuric acid, H2SO4 added with O3 (SOM), H2SO4 added with H2O2 (SPM), H3PO4 added with O3, or H3PO4 added with H2O2, and removing the silicon oxide layer outside of the trench.

Abstract: A method for fabricating a conductive contact is provided, including: providing a semiconductor substrate with a dielectric layer formed thereover and two conductive regions and an isolation element formed therein, wherein the isolation element isolates the two conductive regions from each other; forming an opening in the dielectric layer, exposing a top surface of the isolation element and a portion of a top surface of each of the conductive regions; performing an epitaxy process and forming a conductive semiconductor layer within the opening, overlying the top surface of the isolation element and the portion of the top surface of each of the conductive regions; and forming a conductive layer in the opening, overlying the conductive semiconductor layer and filling the opening.

Abstract: A method of bevel trimming a three dimensional (3D) semiconductor device is disclosed, comprising providing a substrate with stack layers thereon and through substrate vias (TSV) therein, wherein an edge of the substrate is curved, performing a bevel trimming step to the curved edge of the substrate for obtaining a planar edge, and thinning the substrate to expose the through substrate vias.