A vertical memory device may include a first conductive line structure and an address decoder. The first conductive line structure may be on a substrate. The first conductive line structure may include conductive lines and insulation layers alternately and repeatedly stacked in a direction perpendicular to the substrate. The address decoder may be connected to a first end of each of conductive lines included in the first conductive line structure. The address decoder may apply electrical signal to the conductive lines. In each of the conductive lines, a first portion adjacent to the first end and a second portion adjacent to a second end may have different shapes. A first resistance in the first portion may be lower than a second resistance in the second portion. RC delay of the conductive lines may be reduced.

A semiconductor device includes a first substrate, circuit elements, lower interconnection lines, a second substrate, gate electrodes stacked on the second substrate to be spaced apart from each other in a first direction and forming first and second stack structures, channel structures penetrating through the gate electrodes, and first and second contact plugs penetrating through the first and second stack structures, respectively, and connected to the gate electrodes. The first stack structure has first pad areas in which the gate electrodes extend further than upper gate electrodes, respectively, and are connected to the first contact plugs, respectively. The second stack structure has second pad areas in which the gate electrodes extend further than upper gate electrodes, respectively, and are connected to the second contact plugs, respectively. The first and second pad areas are offset in relation to each other so as not to overlap each other in the first direction.

Disclosed are novel structures and methods for 3D NVM built with vertical transistors above a logic layer. A first embodiment has a conductive film under the transistors and serving as a common node in a memory block. The conductive film may be from a semiconductor layer used to build the transistors. Metal lines are disposed above the transistors for connection through 3D vias to underlying circuitry. Contact plugs may be formed between transistors and metal lines. The conductive film may be coupled to underlying circuitry through contacts on the conductive film or through interconnect vias underneath the film. A second embodiment has conductive lines disposed under the transistors. Either of conductive lines and metal lines may serve as source lines and the other as bit lines for the memory. For low parasitic resistances, the conductive lines may be shorted to bypass metal lines residing in underlying logic layer.

A read-only memory cell array includes a first storage state memory cell and a second storage state memory cell. The first storage state memory cell includes a first transistor and a second transistor. The first transistor is connected to a source line and a word line. The second transistor is connected to the first transistor and a first bit line. The second storage state memory cell includes a third transistor and a fourth transistor. The third transistor is connected to the source line and the word line. The fourth transistor is connected to the third transistor and a second bit line. A gate terminal of the fourth transistor is connected to a gate terminal of the third transistor.

An integrated circuit device includes a substrate, a peripheral wiring circuit that includes a bypass via and is disposed on the substrate, a peripheral circuit that includes an interlayer insulating layer surrounding at least a portion of the peripheral wiring circuit, and a memory cell array disposed on and overlapping the peripheral circuit. The memory cell array includes a base substrate, a plurality of gate lines disposed on the base substrate, and a plurality of channels penetrating the plurality of gate lines. The integrated circuit device further includes a barrier layer interposed between the peripheral circuit and the memory cell array. The barrier layer includes a bypass hole penetrating from a top surface to a lower surface of the barrier layer. The bypass via is disposed in the bypass hole.

A semiconductor device includes a substrate having a cell region and a connection region, a first stack structure with a plurality of first gate layers and a plurality of first interlayer insulating layers, and a second stack structure with a plurality of second gate layers and a plurality of second interlayer insulating layers . Each of the first gate layers includes a central portion in the cell region of the substrate and an end portion in the connection region of the substrate. Each of the second gate layers includes a central portion in the cell region of the substrate and an end portion in the connection region of the substrate. A thickness difference between the end and central portions of each first gate layer is different from a thickness difference between the end and central portions of each second gate layer.

A semiconductor device according to one embodiment includes: a semiconductor substrate; a peripheral circuit provided on the semiconductor substrate; and a stacked body provided above the peripheral circuit, which has a memory cell array. The peripheral circuit includes: a metal film including silicon; a silicide film stacked on the metal film; and a barrier metal film stacked on the silicide film.

A semiconductor device includes a peripheral circuit structure including a lower substrate, a plurality of circuits formed on the lower substrate, and a plurality of wiring layers connected to the plurality of circuits, an upper substrate covering the peripheral circuit structure and including a through opening, a memory stack structure including a plurality of gate lines, a memory cell contact passing through at least one of the plurality of gate lines to contact one gate line from among the plurality of gate lines, the memory cell contact extending to the peripheral circuit structure through the through opening and being configured to be electrically connected to a first wiring layer from among the plurality of wiring layers, and a plurality of dummy channel structures passing through at least one of the plurality of gate lines to extend to the peripheral circuit structure through the through opening.

A semiconductor storage device includes a stacked body in which a plurality of conductive layers and a plurality of insulating layers are alternately stacked along a stacking direction, and a plurality of first pillars extending in the stacked body along the stacking direction to form memory cells at intersections with at least some of the plurality of conductive layers. The stacked body includes a stair portion in which the plurality of conductive layers are stacked in a stepped manner at a position separated from the plurality of first pillars in a first direction intersecting the stacking direction. At least a lowermost insulating layer of the plurality of insulating layers has at least one bending portion bent in the stacking direction at an end of the plurality of conductive layers in the stair portion along the first direction.

The present application discloses a semi-floating gate device. A floating gate structure covers a selected area of a first well region and is used to form a conductive channel. The floating gate structure further covers a surface of a lightly doped drain region, and a floating gate material layer and the lightly doped drain region contact at a dielectric layer window to form a PN structure. A source region is self-aligned with a first side surface of the floating gate structure. A first control gate is superposed on a top of the floating gate structure. A second control gate is disposed on a surface of the lightly doped drain region between the drain region and a second side surface of the floating gate structure. The first control gate and the second control gate are isolated by an inter-gate dielectric layer.