A semiconductor cell structure includes four pairs of conductive segments, a first gate-strip, and a second gate-strip. A first conductive segment is configured to have a first supply voltage, and a second conductive segment is configured to have a second supply voltage. Each of the first gate-strip and the second gate-strip intersects an active zone over a channel region of a transistor. The first gate-strip is conductively connected to the second conductive segment. The semiconductor cell structure also includes a first dummy gate-strip and a second dummy gate-strip. The first dummy gate-strip separates from the first gate-strip by one CPP. The second dummy gate-strip separates from the second gate-strip by one CPP. The first gate-strip and the second gate-strip are separated from each other by two CPPs. The dummy gate-strip and the second dummy gate-strip are separated from each other by four CPPs.

A semiconductor cell structure includes four pairs of conductive segments, a first gate-strip, and a second gate-strip. A first conductive segment is configured to have a first supply voltage, and a second conductive segment is configured to have a second supply voltage. Each of the first gate-strip and the second gate-strip intersects an active zone over a channel region of a transistor. The first gate-strip is conductively connected to the second conductive segment. The semiconductor cell structure also includes a first dummy gate-strip and a second dummy gate-strip. The first dummy gate-strip separates from the first gate-strip by one CPP. The second dummy gate-strip separates from the second gate-strip by one CPP. The first gate-strip and the second gate-strip are separated from each other by two CPPs. The dummy gate-strip and the second dummy gate-strip are separated from each other by four CPPs.

A stacked film is a stacked film including an oxide film, and a metal film provided on the oxide film, in which the oxide film includes a ZrO.sub.2 film of which a main surface is a (001) plane, the metal film includes a Pt film or a Pd film that has a single orientation and of which a main surface is a (001) plane, and a [100] axis of the ZrO.sub.2 film and a [100] axis of the metal film are parallel to an interface between the oxide film and the metal film, and the axes of both are parallel to each other.

A method for separating semiconductor die stacks of a chip-on-wafer assembly is disclosed herein. In one example, divider walls are arranged in a pattern on a first surface of a device wafer such that regions between the divider walls define mounting sites. Die stacks are mounted to the device wafer, wherein individual die stacks are located at a corresponding mounting site between the divider walls. The device wafer is cut through from a second surface that is opposite the first surface of the device wafer, and the divider walls are removed from between the die stacks to form a vacant lane between adjacent die stacks.

A method for separating semiconductor die stacks of a chip-on-wafer assembly is disclosed herein. In one example, divider walls are arranged in a pattern on a first surface of a device wafer such that regions between the divider walls define mounting sites. Die stacks are mounted to the device wafer, wherein individual die stacks are located at a corresponding mounting site between the divider walls. The device wafer is cut through from a second surface that is opposite the first surface of the device wafer, and the divider walls are removed from between the die stacks to form a vacant lane between adjacent die stacks.

A method of manufacturing a semiconductor device includes forming a silicon nitride film having an opening portion on a semiconductor substrate, forming a silicon oxide film on the silicon nitride film and on a side face of the opening portion, performing an etching treatment to the silicon oxide film so that a sidewall is formed on the side face of the opening portion, forming a trench on the semiconductor substrate with use of the sidewall and the silicon nitride film as a mask, and forming an insulating layer in the trench. The step of forming the silicon oxide film includes oxidizing the silicon nitride film with a plasma oxidation method or a radical oxidation method.

A reduced size non-volatile memory cell array is achieved by forming first trenches in an insulation layer in the row direction, filling the first trenches with insulation material, forming second trenches in the insulation layer in the column direction, forming the STI isolation material in the second trenches, and forming the source regions through the first trenches. Alternately, the STI isolation regions can be made continuous, and the source diffusion implant has sufficient energy to form continuous source line diffusions that each extend across the active regions and under the STI isolation regions. This allows control gates of adjacent memory cell pairs to be formed closer together.

A single-layer circuit board, multi-layer circuit board, and manufacturing methods therefor. The method for manufacturing the single-layer circuit board comprises the following steps: drilling a hole on a substrate, the hole comprising a blind hole and/or a through hole; on a surface of the substrate, forming a photoresist layer having a circuit negative image; forming a conductive seed layer on the surface of the substrate and a hole wall of the hole; removing the photoresist layer, and forming a circuit pattern on the surface of the substrate, wherein forming a conductive seed layer comprises implanting a conductive material below the surface of the substrate and below the hole wall of the hole via ion implantation, and forming an ion implantation layer as at least part of the conductive seed layer.

Provided are a semiconductor structure and a manufacturing method thereof. The manufacturing method includes the following steps. A substrate having a capacitor region and a periphery region is provided, wherein a transistor is formed in the substrate in the capacitor region, and a conductive device is formed in the substrate in the periphery region. A capacitor is formed on the substrate in the capacitance region, wherein the capacitor is electrically connected to the transistor, and an upper electrode layer of the capacitor extends onto the substrate in the periphery region. A protective layer is formed on the upper electrode layer. A doped layer is formed in at least the surface of the protective layer in the capacitor region. An etching process is performed using the doped layer as a mask to remove the protective layer and the upper electrode layer in the periphery region.

The present invention provides a structure for integrating microfluidic devices and electrical biosensors, including: a substrate for carrying an electrical biosensor; a microfluidic channel layer for providing at least a fluid to flow; a cover member for the inflow and outflow of the at least a fluid, and an electrical biosensor, having a biosensing layer and mounted to the cover member in a flip-chip manner; wherein the fluid flows into an inlet, passes the electrical biosensor for sensing and flows out through a fluid outlet.