Abstract: Gloss-based material classification of an object fabricated from an unknown material, particularly where the unknown material is one from a limited set of predetermined materials. The object is illuminated with an area light source such that the object is illuminated from multiple angles. An image of the object is obtained, and specular reflections from the object are measured by analyzing the image. The object material is classified based on a number of high-intensity specular reflections.

Abstract: A multiscale telescopic imaging system is disclosed. The system includes an objective lens, having a wide field of view, which forms an intermediate image of a scene at a substantially spherical image surface. A plurality of microcameras in a microcamera array relay image portions of the intermediate image onto their respective focal-plane arrays, while simultaneously correcting at least one localized aberration in their respective image portions. The microcameras in the microcamera array are arranged such that the fields of view of adjacent microcameras overlap enabling field points of the intermediate image to be relayed by multiple microcameras. The microcamera array and objective lens are arranged such that light from the scene can reach the objective lens while mitigating deleterious effects such as obscuration and vignetting.

Abstract: A multiscale imaging system including microcameras having controllable focus, dynamic range, exposure, and magnification is disclosed. The objective lens forms a three-dimensional image field of a scene. Image regions of the image field are relayed by the microcameras onto their respective focal-plane arrays, which collectively provide a plurality of digital sub-images of the scene. The digital sub-images can then be used to form a composite digital image of the scene that can have enhanced depth-of-field, enhanced dynamic range, parallax views of the scene, or three-dimensionality.

Abstract: Polishing pads are provided that include a substrate for a polishing pad and a plurality of spaced apart members on the substrate and protruding from the substrate. The plurality of members include at least one abrasive layer and at least one chemical additive layer. Related methods of fabricating polishing pads are also provided herein.

Abstract: A contact structure includes a lower conductive pattern disposed on a predetermined region of a semiconductor substrate. The lower conductive layer has a concave region at a predetermined region of a top surface thereof. An embedding conductive layer fills the concave region. The top surface of the embedding conductive layer is placed at least as high as the height of the flat top surface of the lower conductive pattern. A mold layer is disposed to cover the semiconductor substrate, the lower conductive pattern and the embedding conductive layer. An upper conductive pattern is arranged in an intaglio pattern. The intaglio pattern is disposed in the mold layer to expose a predetermined region of the embedding conductive layer.

Abstract: An inductor for a system-on-a-chip and a method for manufacturing the inductor are disclosed. The inductor comprises a conductive line formed by connecting a plurality of conductive patterns grown from a seed layer formed on a lower wiring. The method comprises using an electrolytic plating process or an electroless plating process to grow the plurality of adjacent conductive patterns from the seed layer until they become connected. The method also enables adjusting the height and width of the conductive line to desired levels.

Abstract: A method of manufacturing a semiconductor element, includes forming a lower metal wiring layer and an interlayer insulating film on a substrate, forming an opening through the interlayer insulating film, such that the opening is in communication with an upper surface of the lower metal wiring layer, cleaning the opening, forming a metal wiring line protecting film in the opening, such that the metal wiring line protecting film covers the lower metal wiring layer, washing the opening to remove the metal wiring line protecting film, such that a top surface of the lower metal wiring layer is exposed, and drying the substrate.

Abstract: Polishing apparatus and related methods employ aligned first and second magnetic field sources to adjust the compressive force and/or pressure applied by a carrier head against a target workpiece (such as a wafer) by selectively and controllably generating a repellant or attractive force between the two magnetic field sources.

Abstract: The present invention discloses a metal-insulator-metal (MIM) capacitor and a method for fabricating the MIM capacitor, comprising forming a bottom insulation layer, a capacitor electrode material layer, and a hard mask material layer on a semiconductor substrate having a metal wire thereon; forming a hard mask by etching the hard mask material layer using a photosensitive mask; forming a capacitor electrode by etching the capacitor electrode material layer using the hard mask as an etching mask; and forming a top insulation layer on an entire surface of the semiconductor.

Abstract: An inductor for a system-on-a-chip and a method for manufacturing the inductor are disclosed. The inductor comprises a conductive line formed by connecting a plurality of conductive patterns grown from a seed layer formed on a lower wiring. The method comprises using an electrolytic plating process or an electroless plating process to grow the plurality of adjacent conductive patterns from the seed layer until they become connected. The method also enables adjusting the height and width of the conductive line to desired levels.

Abstract: Methods are provided for fabricating a semiconductor device that include the steps of: sequentially forming a metal interconnection and a protecting layer on a semiconductor substrate; forming a contact hole on the protecting layer; isolating the contact hole by forming a molding layer and an etching stop layer stacked thereon; forming a sacrificial layer on the etching stop layer so as to fill the contact hole; forming a photoresist layer with an opening so as to expose the sacrificial layer and such that the opening of the photoresist layer aligns with the contact hole; forming a trench in the molding layer to penetrate the sacrificial layer and the etching stop layer; and performing a wet etching on the semiconductor substrate having the trench to remove the photoresist layer and the sacrificial layer, wherein the wet etching step is performed using an organic compound and fluoride ion-based buffered solution.

Abstract: A method of manufacturing a semiconductor element, includes forming a lower metal wiring layer and an interlayer insulating film on a substrate, forming an opening through the interlayer insulating film, such that the opening is in communication with an upper surface of the lower metal wiring layer, cleaning the opening, forming a metal wiring line protecting film in the opening, such that the metal wiring line protecting film covers the lower metal wiring layer, washing the opening to remove the metal wiring line protecting film, such that a top surface of the lower metal wiring layer is exposed, and drying the substrate.

Abstract: A contact structure includes a lower conductive pattern disposed on a predetermined region of a semiconductor substrate. The lower conductive layer has a concave region at a predetermined region of a top surface thereof. An embedding conductive layer fills the concave region. The top surface of the embedding conductive layer is placed at least as high as the height of the flat top surface of the lower conductive pattern. A mold layer is disposed to cover the semiconductor substrate, the lower conductive pattern and the embedding conductive layer. An upper conductive pattern is arranged in an intaglio pattern. The intaglio pattern is disposed in the mold layer to expose a predetermined region of the embedding conductive layer.

Abstract: A method for use in manufacturing a semiconductor device includes forming a photoresist pattern on a substrate, performing first etching process in which an initial trench is formed using the photoresist pattern as a mask, and performing second distinct etching process to enlarge the initial trench. Thus, the initial trench can be formed using the photoresist pattern having a stable structure. Thereafter, the trench is enlarged using an etching solution having a composition based on the material in which the initial trench is formed, e.g., silicon substrate or an insulation film. Therefore, a metal wiring, an isolation film or a contact can be formed in the enlarged trench to desired dimensions.

Abstract: A method for use in manufacturing a semiconductor device includes forming a photoresist pattern on a substrate, performing first etching process in which an initial trench is formed using the photoresist pattern as a mask, and performing second distinct etching process to enlarge the initial trench. Thus, the initial trench can be formed using the photoresist pattern having a stable structure. Thereafter, the trench is enlarged using an etching solution having a composition based on the material in which the initial trench is formed, e.g., a silicon substrate or an insulation film. Therefore, a metal wiring, an isolation film or a contact can be formed in the enlarged trench to desired dimensions.

Abstract: A contact structure includes a lower conductive pattern disposed on a predetermined region of a semiconductor substrate. The lower conductive layer has a concave region at a predetermined region of a top surface thereof. An embedding conductive layer fills the concave region. The top surface of the embedding conductive layer is placed at least as high as the height of the flat top surface of the lower conductive pattern. A mold layer is disposed to cover the semiconductor substrate, the lower conductive pattern and the embedding conductive layer. An upper conductive pattern is arranged in an intaglio pattern. The intaglio pattern is disposed in the mold layer to expose a predetermined region of the embedding conductive layer.

Abstract: A method of forming a metal pattern using a selective electroplating process is provided. First, a dielectric layer is formed on an underlying layer. Then, a trench defining blanket region is formed by patterning the dielectric layer. A diffusion barrier layer is conformally formed in the trench and on the blanket region. A polishing/plating stop layer and an upper seed layer are conformally formed on the diffusion barrier layer in a successive manner. The polishing/plating layer in the blanket region is exposed by selectively removing the upper seed layer in the blanket region, and, at the same time, a seed layer pattern remaining in the trenches is formed. An upper conductive layer is formed to fill the trench surrounded by the seed layer pattern using an electroplating process. Then, the dielectric layer in the blanket region is exposed by planarizing the upper conductive layer, the polishing/plating stop layer, the seed layer pattern, and the diffusion barrier layer.

Abstract: Polishing apparatus and related methods employ aligned first and second magnetic field sources to adjust the compressive force and/or pressure applied by a carrier head against a target workpiece (such as a wafer) by selectively and controllably generating a repellant or attractive force between the two magnetic field sources.

Abstract: Polishing apparatus and related methods employ aligned first and second magnetic field sources to adjust the compressive force and/or pressure applied by a carrier head against a target workpiece (such as a wafer) by selectively and controllably generating a repellant or attractive force between the two magnetic field sources.

Abstract: A plasma reactor includes more than two electrode plates 1, each electrode plate 1 including a dielectric members and an electrode 16 protected from a discharge space 50 by the dielectric member and having an electric-connecting coupling hole on one side and a non-electric-connecting coupling hole on the other side, the electric-connecting coupling hole having a shoulder 7 on which the electrode 16 is exposed, the electrode plates 1 being stacked such that a gap is interposed between the adjacent electrode plates 1 and the electric-connecting coupling hole and the non-electric-connecting coupling hole are alternately arranged; spacers 32, 34 installed between the adjacent electrode plates; and an electric-conductive coupler 40 which is inserted through an array of the electric-connecting coupling hole and the non-electric-connecting coupling hole to couple the electrode plates 1 together, and is caught into contact with the shoulder 7 to be electric-connected with the electrode 16; wherein electricity is appl