A semiconductor substrate (1) includes a region (AR3) between a region (AR1) and a region (AR2), a control gate electrode (CG) is formed on an upper surface (TS1) of the region (AR1), and a memory gate electrode (MG) is formed on an upper surface (TS2) of the region (AR2). The upper surface (TS2) is lower than the upper surface (TS1), and the region (AR3) has a connection surface (TS3) connecting the upper surface (TS1) and the upper surface (TS2). An end (EP1) of the connection surface (TS3) which is on the upper surface (TS2) side is arranged closer to the memory gate electrode (MG) than an end (EP2) of the connection surface (TS3) which is on the upper surface (TS1) side, and is arranged lower than the end (EP2).

A semiconductor device and a fabrication method thereof are provided. The semiconductor device includes a semiconductor structure, a dielectric layer, a metal-semiconductor compound film and a cover layer. The semiconductor structure has an upper surface and a lateral surface. The dielectric layer encloses the lateral surface of the semiconductor structure and exposes the upper surface of the semiconductor structure. The metal-semiconductor compound film is on the semiconductor structure, wherein the dielectric layer exposes a portion of a surface of the metal-semiconductor compound film. The cover layer encloses the portion of the surface of the metal-semiconductor compound film exposed by the dielectric layer, and exposes the dielectric layer.

An optical proximity correction (OPC) verifying method including checking a first location of a first pattern in a layout of a stacked memory device, calculating a shift value of the first pattern according to the first location, obtaining a difference value between the first location and a second location of a second pattern formed through an OPC with respect to the first pattern, and determining whether the OPC is to be performed again, based on the shift value and the difference value.

The present invention provides a semiconductor device that has a shorter distance between the bit lines and easily achieves higher storage capacity and density. The semiconductor device includes: first bit lines and an insulating layer that is provided between the first bit lines and in a groove. First faces of the first bit lines are aligned on a first line and second faces of the first bit lines are aligned on a second line. A first face of the insulating layer is disposed at a third line that is a first distance from the first line in a first direction and a second face of the insulating layer is disposed at a fourth line that is a second distance from the second line in a second direction.

The present disclosure provides, in accordance with some illustrative embodiments, a semiconductor device structure including a hybrid substrate comprising an SOI region and a bulk region, the SOI region comprising an active semiconductor layer, a substrate material, and a buried insulating material interposed between the active semiconductor layer and the substrate material, and the bulk region being provided by the substrate material, an insulating structure formed in the hybrid substrate, the insulating structure separating the bulk region and the SOI region, and a gate electrode formed in the bulk region, wherein the insulating structure is in contact with two opposing sidewalls of the gate electrode.

Provided is a stable manufacturing method for a semiconductor device. In the manufacturing method for a semiconductor device, first, fins with an equal width are formed in each of a memory cell portion and a logic portion of a semiconductor substrate. Then, the fins in the logic portion are etched with the fins in the memory cell covered with a mask film, thereby fabricating fins in the logic portion, each of which is narrower than the fin formed in the memory cell portion.

According to an embodiment, a semiconductor memory device comprises: a semiconductor substrate; a memory cell array configured having a plurality of memory units, each of the memory units including a plurality of memory cells connected in series, the plurality of memory cells being stacked, the plurality of memory units involving a first memory unit and a second memory unit; and a plurality of bit lines connected to ends of each of the memory units in the memory cell array. The first memory unit and the second memory unit are arranged in a staggered manner by the first memory unit being displaced in a row direction with respect to the second memory unit by an amount less than an arrangement pitch in a row direction of the first memory unit or the second memory unit.

Three-dimensional (3D) semiconductor memory devices are provided. A 3D semiconductor memory device includes an electrode structure on a substrate. The electrode structure includes gate electrodes stacked on the substrate. The gate electrodes include electrode pad regions. The 3D semiconductor memory device includes a dummy vertical structure penetrating one of the electrode pad regions. The dummy vertical structure includes a dummy vertical semiconductor pattern and a contact pattern extending from a portion of the dummy vertical semiconductor pattern toward the substrate.

An annular dielectric spacer can be formed at a level of a joint-level dielectric material layer between vertically neighboring pairs of alternating stacks of insulating layers and spacer material layers. After formation of a memory opening through multiple alternating stacks and formation of a memory film therein, an anisotropic etch can be performed to remove a horizontal bottom portion of the memory film. The annular dielectric spacer can protect underlying portions of the memory film during the anisotropic etch. In addition, a silicon nitride barrier may be employed to suppress hydrogen diffusion at an edge region of peripheral devices.

An illustrative device disclosed herein includes a first memory cell comprising a first memory gate positioned above an upper surface of a semiconductor substrate and a second memory cell comprising a second memory gate positioned above the upper surface of the semiconductor substrate. In this example, the device also includes a conductive select gate structure positioned above the upper surface of the semiconductor substrate between the first and second memory gates, wherein the conductive select gate structure is shared by the first and second memory cells.