A semiconductor device includes a substrate; gate electrodes spaced apart from each other and stacked in a direction, perpendicular to an upper surface of the substrate; first and second horizontal conductive layers sequentially stacked between the substrate and the gate electrodes; and a channel structure passing through the gate electrodes and extending perpendicularly, and including a channel layer contacting the first horizontal conductive layer, wherein the channel layer has a region having a reduced diameter below a first level in which a lower surface of a lowermost gate electrode is located, among the gate electrodes, and the channel structure further includes a metal silicide region located below the first level and in the channel structure to contact the channel layer.

A semiconductor device includes a substrate provided with a decoupling capacitor and plurality of circuit elements disposed along a first direction, and a plurality of first wiring line patterns disposed in a first wiring line layer over the substrate, including a power routing pattern coupled to the decoupling capacitor and a plurality of internal wiring line patterns coupled to the plurality of circuit elements. The plurality of first wiring line patterns extend in the first direction, and are aligned in conformity with virtual wiring line pattern tracks which are defined at a first pitch along a second direction intersecting the first direction and parallel to the substrate.

The invention discloses a dynamic random access memory (DRAM) device and a method of fabricating such DRAM device. The DRAM device according to the invention includes a plurality of bit lines formed on a semiconductor substrate, a plurality of first isolation stripes, a plurality of second isolation stripes, a plurality of transistors formed between the first isolation stripes and the second isolation stripes, a plurality of word lines, and a plurality of capacitors formed above the first isolation stripes and the second isolation stripes. The semiconductor substrate defines a longitudinal direction, a transverse direction, a normal direction, a plurality of columns in the longitudinal direction, and a plurality of rows in the transverse direction. The first isolation stripes and the second isolation stripes extend in the longitudinal direction. Each transistor corresponds to one of the columns and one of the rows. The transistors on one side of each first isolation stripe and the transistors on the other side of said one first isolation stripe are staggeredly arranged. Each word line corresponds to one of the columns and connects the gate conductors of the transistors along the corresponding column. Each capacitor corresponds to one of the transistors and connects the source region of the corresponding transistor.

Some embodiments include methods of forming integrated assemblies. A conductive structure is formed to include a semiconductor-containing material over a metal-containing material. An opening is formed to extend into the conductive structure. A conductive material is formed along a bottom of the opening. A stack of alternating first and second materials is formed over the conductive structure either before or after forming the conductive material. Insulative material and/or channel material is formed to extend through the stack to contact the conductive material. Some embodiments include integrated assemblies.

A semiconductor memory device includes an electrode structure including a plurality of electrode layers and a plurality of interlayer dielectric layers which are alternately stacked on a source plate defined with a cell area and a connection area in a first direction; a vertical channel passing through the electrode structure in the cell area; a hard mask pattern disposed on the electrode structure in the connection area, and having a plurality of opening holes; a plurality of contact holes defined in the electrode structure under the opening holes, and exposing pad areas of the electrode layers; and a slit dividing the hard mask pattern into units smaller than the electrode structure in the connection area.

A semiconductor device is disclosed. The semiconductor device includes a first slit, at least one word line, and a second slit. The first slit is disposed at a boundary between contiguous memory blocks to isolate the memory blocks from each other, and includes a first outer slit and a second outer slit, the second outer slit is spaced apart in a first direction from the first outer slit by a predetermined distance. The word line is disposed, between the first and second outer slits, including a center region having a first end and a second end, and an edge region located at the first end and a second end of the center region, and the second slit is disposed at the center region that isolate area of the word line in the center region on either side of the second slit, wherein the word line is continuous in the edge regions.

A memory device is disclosed. The disclosed memory device may include a first wafer, and a second wafer stacked on and bonded to the first wafer. The first wafer may include a cell structure including a memory cell array; and a first logic structure disposed under the cell structure, and including a column control circuit. The second wafer may include a second logic structure including a row control circuit.

A memory device with a three-dimensional (3D) staircase memory stack includes dummy connectors proximate semi-isolated connectors. The memory device includes multiple wordlines stacked in a 3D staircase stack, which includes a wordline at an edge of a region of the staircase. The memory device includes vertical connectors through an isolation layer on the 3D staircase stack to connect the wordlines with conductive lines in an access layer. A wordline at the edge of the region of the staircase has a vertical connector that will be adjacent a connector on one side and not on the other side. The memory device includes at least one dummy vertical connector on the edge side of the vertical connector of the wordline on the edge, wherein the dummy vertical connector does not electrically connect a wordline of the 3D staircase stack to a conductive line in the access layer.

The present application provides a three-dimensional memory and a fabrication method for the same. The method includes forming a storage stack structure on a substrate and forming a storage channel structure that penetrates the storage stack structure, forming a selection stack structure stacked on the storage stack structure and forming a selection channel structure that penetrates the selection stack structure and is connected to the storage channel structure. The width of the selection channel structure is smaller than the width of the storage channel structure on a plane parallel to the substrate and forming a TSG cut structure that penetrates the selection stack structure. The three-dimensional memory and the fabrication method for the same increases the process window for the TSG cut structure formed between the selection channel structures and improves the storage density.

A method includes disposing a layer stack on a substrate, the layer stack including a number of levels. A first control gate structure is formed in a first level of the number of levels by: forming a first opening through a dielectric layer of the first level and a sacrificial layer of the first level; removing a remaining portion of the sacrificial layer of the first level to form a first cavity; and disposing a first conductive layer in the first cavity. A second control gate structure is formed in a second level below the first level by: extending the first opening into a dielectric layer of the second level and a sacrificial layer of the second level to form a second opening; removing a remaining portion of the sacrificial layer of the second level to form a second cavity; and disposing a second conductive layer in the second cavity.