A semiconductor device includes a cell array including a source structure, a peripheral circuit, an interconnection structure located between the cell array and the peripheral circuit and electrically coupled to the peripheral circuit, and a decoupling structure configured to prevent a coupling capacitor that occurs between the cell array and the interconnection structure.

A semiconductor memory device according to an embodiment comprises: conductive layers stacked in a vertical direction on a semiconductor substrate; and first and columnar bodies that extend in the vertical direction, the first and second columnar bodies each comprising: a first film; a second film disposed on the first film; and a semiconductor film, and the first film of the second columnar body having an upper end positioned higher than a first position lower than a first conductive layer and lower than a second position higher than the first conductive layer and a lower end positioned at or lower than the first position, and the second film of the second columnar body having an upper end positioned higher than the second position and a lower end positioned lower than the first position.

A semiconductor device includes a base member, a first structure body, a second structure body, a first contact portion, a second contact portion, and a first post. The first structure body is provided above the base member. The first structure body has a first terrace in a front surface of a first end portion of the first electrode layer. The second structure body is provided on the first structure body other than the first end portion. The second structure body has a second terrace in a front surface of a second end portion of the second electrode layer. The side surface of the second electrode layer is at a first level difference between the first terrace and the second terrace. The first post is disposed between the first contact portion and the second contact portion. The first post crosses the first level difference.

A non-volatile memory device according to an aspect of the present disclosure includes a substrate, a plurality of word lines stacked over the substrate and having a stepwise pattern, wherein the plurality of word lines each have a pad region, and a plurality of contact plugs coupled to the respective pad regions of the word lines, wherein a width of a pad region of a first one of the plurality of word lines is greater than a width of a pad region of a second word line lower than the first word line.

A three-dimensional nonvolatile memory device and a method for fabricating the same include a semiconductor substrate, a plurality of active pillars, a plurality of gate electrodes, and a plurality of supporters. The semiconductor substrate includes a memory cell region and a contact region. The active pillars extend in the memory cell region perpendicularly to the semiconductor substrate. The gate electrodes intersect the active pillars, extend from the memory cell region to the contact region and are stacked on the semiconductor substrate. The supporters extend in the contact region perpendicularly to the semiconductor substrate to penetrate at least one or more of the gate electrodes.

Some embodiments include apparatuses and methods having a substrate, a memory cell string including a body, a select gate located in a level of the apparatus and along a portion of the body, and control gates located in other levels of the apparatus and along other respective portions of the body. At least one of such apparatuses includes a conductive connection coupling the select gate or one of the control gates to a component (e.g., transistor) in the substrate. The connection can include a portion going through a portion of at least one of the control gates.

In some embodiments, the present disclosure relates to an integrated chip. The integrated chip includes a plurality of transistor devices disposed on or within a substrate and a plurality of memory devices disposed on or within the substrate. A first isolation structure is disposed within the substrate between the plurality of transistor devices and the plurality of memory devices. A dummy gate structure is arranged on the first isolation structure and has a top surface that is vertically above top surfaces of the plurality of transistor devices and the plurality of memory devices.

According to an embodiment, a semiconductor memory device includes a semiconductor substrate, a control circuit arranged on the semiconductor substrate, and a memory cell array arranged above the control circuit. The memory cell array includes a plurality of three-dimensionally-arranged memory cells, and is controlled by the control circuit. A first nitride layer is arranged between the control circuit and the memory cell array, and a second nitride layer is arranged between the control circuit and the first nitride layer.

In some embodiments, the present disclosure relates to a method of forming an integrated chip. The method includes forming a plurality of memory devices within an embedded memory region of a substrate and forming a plurality of transistor devices within a logic region of the substrate. A first isolation structure is formed within a boundary region of the substrate disposed between the logic region and the embedded memory region. The first isolation structure is formed within a recess in the substrate. A logic wall is formed over the first isolation structure. The logic wall surrounds the embedded memory region and has a first height that is greater than heights of the plurality of memory devices.

A vertical memory device includes a substrate having a peripheral circuit structure, first gate patterns having first gate pad regions stacked vertically from the substrate, vertical channel structures penetrating the first gate patterns, first gate contact structures each extending vertically to a corresponding first gate pad region, mold patterns stacked vertically from the substrate, the mold patterns each being positioned at the same height from the substrate with a corresponding gate pattern, peripheral contact structures penetrating the mold patterns to be connected to the peripheral circuit structure, a first block separation structure disposed between the first gate contact structures and the peripheral contact structures, and a first peripheral circuit connection wiring extending across the first block separation structure to connect one of the first gate contact structures to one of the peripheral contact structures.