Abstract: A semiconductor package includes a first semiconductor chip and a second semiconductor chip which are disposed side-by-side on a surface of a package substrate. A heat insulation wall is disposed between the first semiconductor chip and the second semiconductor chip. The heat insulation wall thermally isolates the first semiconductor chip from the second semiconductor chip.

Abstract: The present disclosure relates to a preparation method of a methionine-metal chelate, and the methionine-metal chelate, which is prepared by first reacting Ca(OH)2 and methionine and adding metal chloride salts, can be used as feeds and feed additives.

Abstract: A semiconductor package includes a package substrate, a first chip stack, a second chip stack, and a supporting block. The first chip stack includes first semiconductor chips stacked on the package substrate to be offset in a first direction, and the second chip stack includes second semiconductor chips stacked on the first chip stack to be offset in a second direction. The supporting block includes a through via structure. The second chip stack is supported by the first chip stack and the supporting block.

Abstract: A semiconductor package includes a first semiconductor chip and a second semiconductor chip which are disposed side-by-side on a surface of a package substrate. A heat insulation wall is disposed between the first semiconductor chip and the second semiconductor chip. The heat insulation wall thermally isolates the first semiconductor chip from the second semiconductor chip.

Abstract: A plasma processing apparatus includes a plasma chamber, an electrostatic chuck disposed in the plasma chamber and a pressure control ring disposed in the plasma chamber. The pressure control ring includes a body surrounding an electrostatic chuck in a plan view, an exhaust part disposed in a portion of the body along a first direction, the exhaust part configured to induce a flow of gas in the plasma chamber toward the first direction in a plan view, and a blocking part disposed in another portion of the body along a second direction perpendicular to the first direction in a plan view, the blocking part configured to block the flow of the gas in the second direction.

Abstract: A method includes providing a device under test, which includes a lower test layer and an upper test layer that is stacked on the lower test layer and includes an overhang protruding past an edge of the lower test layer by a predetermined length, fixing the lower test layer onto a mounting stage, and measuring adhesive force of an interlayer adhesive layer in a tensile mode by applying a load to a bottom surface of the overhang of the upper test layer in a first direction. An apparatus includes a mounting stage fixing the device under test, a load applying tip applying the load to the bottom surface of the overhang, a location adjuster adjusting a distance between the device under test and the load carrying tip, a load cell detecting a magnitude of the applied load, and a controller controlling the location adjuster and the load cell.

Abstract: A semiconductor package includes a first semiconductor chip and a second semiconductor chip which are disposed side-by-side on a surface of a package substrate. A heat insulation wall is disposed between the first semiconductor chip and the second semiconductor chip. The heat insulation wall thermally isolates the first semiconductor chip from the second semiconductor chip.

Abstract: A method includes providing a device under test, which includes a lower test layer and an upper test layer that is stacked on the lower test layer and includes an overhang protruding past an edge of the lower test layer by a predetermined length, fixing the lower test layer onto a mounting stage, and measuring adhesive force of an interlayer adhesive layer in a tensile mode by applying a load to a bottom surface of the overhang of the upper test layer in a first direction. An apparatus includes a mounting stage fixing the device under test, a load applying tip applying the load to the bottom surface of the overhang, a location adjuster adjusting a distance between the device under test and the load carrying tip, a load cell detecting a magnitude of the applied load, and a controller controlling the location adjuster and the load cell.

Abstract: A method includes providing a device under test, which includes a lower test layer and an upper test layer that is stacked on the lower test layer and includes an overhang protruding past an edge of the lower test layer by a predetermined length, fixing the lower test layer onto a mounting stage, and measuring adhesive force of an interlayer adhesive layer in a tensile mode by applying a load to a bottom surface of the overhang of the upper test layer in a first direction. An apparatus includes a mounting stage fixing the device under test, a load applying tip applying the load to the bottom surface of the overhang, a location adjuster adjusting a distance between the device under test and the load carrying tip, a load cell detecting a magnitude of the applied load, and a controller controlling the location adjuster and the load cell.

Abstract: A method includes providing a device under test, which includes a lower test layer and an upper test layer that is stacked on the lower test layer and includes an overhang protruding past an edge of the lower test layer by a predetermined length, fixing the lower test layer onto a mounting stage, and measuring adhesive force of an interlayer adhesive layer in a tensile mode by applying a load to a bottom surface of the overhang of the upper test layer in a first direction. An apparatus includes a mounting stage fixing the device under test, a load applying tip applying the load to the bottom surface of the overhang, a location adjuster adjusting a distance between the device under test and the load carrying tip, a load cell detecting a magnitude of the applied load, and a controller controlling the location adjuster and the load cell.

Abstract: A CMOS image sensor manufacturing method may include forming an interlayer insulating film over a semiconductor substrate in which a plurality of photodiodes are formed, forming a plurality of color filter layers corresponding to the photodiodes over the interlayer insulating film, forming a flattening layer over an entire surface of the semiconductor substrate including the respective color filter layers, forming gap insulating films over the flattening layer and over boundaries of the color filter layers, and forming micro-lenses over the flattening layer between the gap insulating films, to correspond to the respective photodiodes.

Abstract: Disclosed are semiconductor devices and methods for fabricating the same. According to one embodiment, the method includes sequentially forming a gate insulation layer and a conductive layer on a semiconductor substrate. A buried impurity region is then formed in the semiconductor substrate. Thus, the gate insulation layer is formed before forming the buried impurity region, thereby substantially reducing impurity diffusion that can be caused by a thermal process for forming the gate insulation layer. In addition, the gate insulation layer is not exposed, thus protecting the gate insulation layer from being recessed.

Abstract: Disclosed are semiconductor devices and methods for fabricating the same. According to one embodiment, the method includes sequentially forming a gate insulation layer and a conductive layer on a semiconductor substrate. A buried impurity region is then formed in the semiconductor substrate. Thus, the gate insulation layer is formed before forming the buried impurity region, thereby substantially reducing impurity diffusion that can be caused by a thermal process for forming the gate insulation layer. In addition, the gate insulation layer is not exposed, thus protecting the gate insulation layer from being recessed.

Abstract: Disclosed are semiconductor devices and methods for fabricating the same. According to one embodiment, the method includes sequentially forming a gate insulation layer and a conductive layer on a semiconductor substrate. A buried impurity region is then formed in the semiconductor substrate. Thus, the gate insulation layer is formed before forming the buried impurity region, thereby substantially reducing impurity diffusion that can be caused by a thermal process for forming the gate insulation layer. In addition, the gate insulation layer is not exposed, thus protecting the gate insulation layer from being recessed.

Abstract: Disclosed are semiconductor devices and methods for fabricating the same. According to one embodiment, the method includes sequentially forming a gate insulation layer and a conductive layer on a semiconductor substrate. A buried impurity region is then formed in the semiconductor substrate. Thus, the gate insulation layer is formed before forming the buried impurity region, thereby substantially reducing impurity diffusion that can be caused by a thermal process for forming the gate insulation layer. In addition, the gate insulation layer is not exposed, thus protecting the gate insulation layer from being recessed.