A semiconductor device may comprise a plurality of conductive lines and a plurality of contact plugs. The plurality of conductive lines may include a first conductive line a second conductive line. The plurality of contact plugs may include a first contact plug and a second contact plug. The first contact plug may have a first pillar portion and a first protruding portion protruding from a sidewall of the first pillar portion at a first depth, so as to be in alignment and contact with a sidewall of the first conductive line. The second contact plug may have a second pillar portion and a second protruding portion protruding from a sidewall of the second pillar portion at a second depth, so as to be in alignment and contact with a sidewall of the second conductive line.

A memory device includes a lower structure, a stacked structure on the lower structure, the stacked structure including horizontal layers and interlayer insulating layers alternately stacked in a vertical direction, and each of the horizontal layers including a gate electrode, a vertical structure penetrating through the stacked structure in the vertical direction, the vertical structure having a core region, a pad pattern with a pad metal pattern on the core region, a dielectric structure including a first portion facing a side surface of the core region, a second portion facing at least a portion of a side surface of the pad metal pattern, and a data storage layer, and a channel layer between the dielectric structure and the core region, a contact structure on the vertical structure, and a conductive line on the contact structure.

A semiconductor device includes a peripheral circuit region including a first substrate and circuit devices on the first substrate, a memory cell region including a second substrate on the first substrate, a horizontal conductive layer on the second substrate, gate electrodes stacked on the horizontal conductive layer in a first direction perpendicular to an upper surface of the second substrate and spaced apart from each other, and channel structures extending in gate electrodes in the first direction, each of the channel structures including a channel layer in physical contact with the horizontal conductive layer, and a through wiring region including a through contact plug extending in the first direction and electrically connecting the memory cell region to the peripheral circuit region, an insulating region bordering the through contact plug, and dummy channel structures partially extending into the insulating region in the first direction.

According to one embodiment, a semiconductor memory device includes a first conductive layer, a first semiconductor body, a second semiconductor body, a first memory layer, and a second memory layer. The first conductive layer includes first to fourth extension regions, and a first connection region. The first extension region extends in a first direction. The second extension region extends in the first direction and is arranged with the first extension region in the first direction. The third extension region extends in the first direction and is arranged with the first extension region in a second direction crossing the first direction. The fourth extension region extends in the first direction, is arranged with the third extension region in the first direction, and is arranged with the second extension region in the second direction.

A semiconductor storage device includes a base body, a stacked body, a plurality of columns, and a plurality of first contacts. The base body includes a substrate, a semiconductor element on the substrate, a lower wiring layer above the semiconductor element in a thickness direction of the base body and connected to the semiconductor element, and a lower conductive layer above the lower wiring layer in the thickness direction. The stacked body is above the lower conductive layer and including an alternating stack of conductive layers and insulating layers. Each of the columns includes a semiconductor body extending through the stacked body and electrically connected to the lower conductive layer. The plurality of first contacts extend through the stacked body and electrically connected to the lower conductive layer. The lower conductive layer is separately provided under each of the plurality of first contacts.

Provided is a substrate processing method that may prevent the non-uniformity of the thickness of landing pads deposited on each step in a vertical NAND device having a stepped structure. The substrate processing method includes stacking, a plurality of times, a stack structure including an insulating layer and a sacrificial layer and etching the stack structure to form a stepped structure having an upper surface, a lower surface, and a side surface connecting the upper surface and the lower surface. The method also includes forming a barrier layer on the stepped structure, forming a mask layer on the barrier layer and exposing at least a portion of the barrier layer by etching at least a portion of the mask layer with a first etching solution The method further includes etching the exposed barrier layer with a second etching solution and etching the mask layer with a third etching solution.

Some embodiments include an integrated assembly having a first memory region, a second memory region, and an intermediate region between the first and second memory regions. The intermediate region has a first edge proximate the first memory region and has a second edge proximate the second memory region. Channel-material-pillars are arranged within the first and second memory regions. Conductive posts are arranged within the intermediate region. Doped-semiconductor-material is within the intermediate region and is configured as a substantially H-shaped structure having a first leg region along the first edge, a second leg region along the second edge, and a belt region adjacent the panel. Some embodiments include methods of forming integrated assemblies.

Disclosed is a three-dimensional semiconductor device comprising channel regions that penetrate the stack structure and extend in a direction perpendicular to a top surface of the first substrate, a first interlayer dielectric layer on the stack structure, and a peripheral circuit structure on the first interlayer dielectric layer. The peripheral circuit structure includes peripheral circuit elements on a first surface of a second substrate. The peripheral circuit elements are electrically connected to the channel regions and at least one of the gate electrodes. The first substrate has a first crystal plane parallel to the top surface thereof. The second substrate has a second crystal plane parallel to the first surface thereof. An arrangement direction of atoms of the first crystal plane intersects an arrangement direction of atoms of the second crystal plane.

A semiconductor device structure that comprises tiers of alternating dielectric levels and conductive levels and a carbon-doped silicon nitride over the tiers of the staircase structure. The carbon-doped silicon nitride excludes silicon carbon nitride. A method of forming the semiconductor device structure comprises forming stairs in a staircase structure comprising alternating dielectric levels and conductive levels. A carbon-doped silicon nitride is formed over the stairs, an oxide material is formed over the carbon-doped silicon nitride, and openings are formed in the oxide material. The openings extend to the carbon-doped silicon nitride. The carbon-doped silicon nitride is removed to extend the openings into the conductive levels of the staircase structure. Additional methods are disclosed.

A semiconductor device includes a stacked body including stacked insulating layers and stacked conductive layers; a cell plug; a connection contact structure; and a source layer coupled to the cell plug. The cell plug includes upper and lower portions, the connection contact structure includes a first connection contact disposed at substantially the same level as the lower portion of the cell plug, and a second connection contact disposed at substantially the same level as the upper portion thereof, a level at which the first and second connection contacts contact each other is substantially the same as a level at which the upper and lower portions of the cell plug contact each other, and a level of an uppermost portion of the second connection contact is higher than a level of a bottom surface of the source layer, and is lower than a level of a top surface thereof.