According to an embodiment, a non-volatile memory device includes a first conductive layer, electrodes, an interconnection layer and at least one semiconductor layer. The electrodes are arranged between the first conductive layer and the interconnection layer in a first direction perpendicular to the first conductive layer. The interconnection layer includes a first interconnection and a second interconnection. The semiconductor layer extends through the electrodes in the first direction, and is electrically connected to the first conductive layer and the first interconnection. The device further includes a memory film between each of the electrodes and the semiconductor layer, and a conductive body extending in the first direction. The conductive body electrically connects the first conductive layer and the second interconnection, and includes a first portion and a second portion connected to the second interconnection.

The second portion has a width wider than the first portion.

A three-dimensional semiconductor memory device including a first peripheral circuit including different decoder circuits, a first memory on the first peripheral circuit, the first memory including a first stack structure having first electrode layers stacked on one another and first inter-electrode dielectric layers therebetween, a first planarized dielectric layer covering an end of the first stack structure, and a through via that penetrates the end of the first stack structure, the through via electrically connected to one of the decoder circuits, and a second memory on the first memory and including a second stack structure having second electrode layers stacked on one another and second inter-electrode dielectric layers therebetween, a second planarized dielectric layer covering an end of the second stack structure, and a cell contact plug electrically connecting one of the second electrode layers to the through via.

A three-dimensional semiconductor memory device including a first peripheral circuit including different decoder circuits, a first memory on the first peripheral circuit, the first memory including a first stack structure having first electrode layers stacked on one another and first inter-electrode dielectric layers therebetween, a first planarized dielectric layer covering an end of the first stack structure, and a through via that penetrates the end of the first stack structure, the through via electrically connected to one of the decoder circuits, and a second memory on the first memory and including a second stack structure having second electrode layers stacked on one another and second inter-electrode dielectric layers therebetween, a second planarized dielectric layer covering an end of the second stack structure, and a cell contact plug electrically connecting one of the second electrode layers to the through via.

A semiconductor device includes a substrate including a lower horizontal layer and an upper horizontal layer and having a cell array region and a connection region, an electrode structure including electrodes, which are stacked above the substrate, and which extend from the cell array region to the connection region, a vertical channel structure on the cell array region that penetrates the electrode structure and is connected to the substrate, and a separation structure on the connection region that penetrates the electrode structure. The lower horizontal layer has a first top surface in contact with a first portion of the separation structure, and a second top surface in contact with a second portion of the separation structure, and an inflection point at which a height of the lower horizontal layer is abruptly changed between the first top surface and the second top surface.

A semiconductor device includes a substrate including a lower horizontal layer and an upper horizontal layer and having a cell array region and a connection region, an electrode structure including electrodes, which are stacked above the substrate, and which extend from the cell array region to the connection region, a vertical channel structure on the cell array region that penetrates the electrode structure and is connected to the substrate, and a separation structure on the connection region that penetrates the electrode structure. The lower horizontal layer has a first top surface in contact with a first portion of the separation structure, and a second top surface in contact with a second portion of the separation structure, and an inflection point at which a height of the lower horizontal layer is abruptly changed between the first top surface and the second top surface.

A method for forming a three-dimensional (3D) memory device includes forming a dielectric stack including a plurality of first/second dielectric layer pairs over a substrate, forming a plurality of channel structures extending in a lateral direction in a core region of the dielectric stack, forming a staircase structure including a plurality of stairs extending along the lateral direction in a staircase region of the dielectric stack, forming a first drain-select-gate (DSG) cut opening extending in the lateral direction in the core region and a second DSG cut opening in the staircase region, and forming a first DSG cut structure in the first DSG cut opening and a second DSG cut structure in the second DSG cut opening.

A cell architecture and a method for placing a plurality of cells to form the cell architecture are provided. The cell architecture includes at least a 1.sup.st cell and a 2.sup.nd cell placed next to each other in a cell width direction, wherein the 1.sup.st cell includes a one-fin connector which is formed around a fin among a plurality of fins of the 1.sup.st cell, and connects a vertical field-effect transistor (VFET) of the 1.sup.st cell to a power rail of the 1.sup.st cell, wherein a 2.sup.nd cell includes a connector connected to a power rail of the 2.sup.nd cell, wherein the fin of the 1.sup.st cell and the connector of the 2.sup.nd cell are placed next to each other in the cell width direction in the cell architecture, and wherein the one-fin connector of the 1.sup.st cell and the connector of the 2.sup.nd cell are merged.

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 is disclosed. The device includes a peripheral circuit structure on a substrate, a semiconductor layer on the peripheral circuit structure, an electrode structure on the semiconductor layer, the electrode structure including electrodes stacked on the semiconductor layer, a vertical channel structure penetrating the electrode structure and being connected to the semiconductor layer, a separation structure penetrating the electrode structure, extending in a first direction, and horizontally dividing the electrode of the electrode structure into a pair of electrodes, an interlayered insulating layer covering the electrode structure, and a through contact penetrating the interlayered insulating layer and being electrically connected to the peripheral circuit structure.

A semiconductor memory device according to an embodiment includes first to ninth conductive layers, first and second insulating members, and first to fourth pillars. A distance between the first and second pillars in a cross section including the second conductive layer and the sixth conductive layer is smaller than a distance between the first and second pillars in a cross section including the third conductive layer and the seventh conductive layer. A distance between the third and fourth pillars in a cross section including the fourth conductive layer and the eighth conductive layer is greater than a distance between the third and fourth pillars in a cross section including the fifth conductive layer and the ninth conductive layer.