A semiconductor memory device according to one embodiment, includes an interconnect extending in a first direction, a semiconductor member extending in a second direction crossing the first direction, an electrode provided between the interconnect and the semiconductor member, a first insulating film provided between the interconnect and the electrode, a second insulating film provided between the first insulating film and the electrode, a third insulating film provided between the electrode and the semiconductor member, and a metal-containing layer provided between the first insulating film and the second insulating film or inside the first insulating film, and having a metal surface concentration of 1×10.sup.14 cm.sup.−2 or more and 5×10.sup.15 cm.sup.−2 or less.

A disclosed example to modulate slit stress in a semiconductor substrate includes controlling a first process to apply a first material to a semiconductor substrate. The semiconductor substrate includes a slit between adjacent stacked transistor layers. The first material coats walls of the slit to reduce a first width of the slit between the adjacent stacked transistor layers to a second width. A second process is controlled to apply a second material to the semiconductor substrate. The second material is to be deposited in the second width of the slit. The first material and the second material are to form a solid structure in the slit between the adjacent stacked transistor layers.

A nonvolatile semiconductor memory device that have a new structure are provided, in which memory cells are laminated in a three dimensional state so that the chip area may be reduced. The nonvolatile semiconductor memory device of the present invention is a nonvolatile semiconductor memory device that has a plurality of the memory strings, in which a plurality of electrically programmable memory cells is connected in series. The memory strings comprise a pillar shaped semiconductor; a first insulation film formed around the pillar shaped semiconductor; a charge storage layer formed around the first insulation film; the second insulation film formed around the charge storage layer; and first or nth electrodes formed around the second insulation film (n is natural number more than 1). The first or nth electrodes of the memory strings and the other first or nth electrodes of the memory strings are respectively the first or nth conductor layers that are spread in a two dimensional state.

The present invention provides a semiconductor device that has a shorter distance between the bit lines and easily achieves higher storage capacity and density. The semiconductor device includes: first bit lines and an insulating layer that is provided between the first bit lines and in a groove. First faces of the first bit lines are aligned on a first line and second faces of the first bit lines are aligned on a second line. A first face of the insulating layer is disposed at a third line that is a first distance from the first line in a first direction and a second face of the insulating layer is disposed at a fourth line that is a second distance from the second line in a second direction.

A cross-point memory array includes a plurality of variable resistance memory cell pillars. Adjacent memory cell pillars are separated by a partially filled gap that includes a buried void. In addition, adjacent memory cell pillars include storage material elements that are at least partially interposed by the buried void.

Provided are semiconductor devices and methods of fabricating the same. The semiconductor devices may include a substrate with a cell region and a peripheral region, a gate stack including gates stacked on the cell region of the substrate. At least one edge portion of the gate stack may have a staircase structure. The semiconductor devices may also include a channel that extend through the gate stack and is enclosed by a memory layer and at least two dummy patterns on the substrate. The at least two dummy patterns may be spaced apart from the gate stack and may be spaced apart from each other.

Three directions intersecting each other are referred to as first to third directions. A semiconductor memory device according to embodiments includes a semiconductor substrate having a top surface spread in the first and second directions, and a plurality of conductive layers laminated at predetermined intervals in the third direction on the semiconductor substrate. The semiconductor memory device further includes a columnar semiconductor layer having an interface that is in contact with the semiconductor substrate on a side surface. The columnar semiconductor layer is opposed to the plurality of conductive layers. The columnar semiconductor layer has the third direction as a lengthwise direction. The interface exists in a position deeper than the top surface of the semiconductor substrate in the third direction.

A three-dimensional semiconductor device includes an electrode structure on a substrate that includes a first region and a second region, the electrode structure including a ground selection electrode, cell electrodes, and a string selection electrode which are sequentially stacked on the substrate wherein the ground selection electrode, the cell electrodes, and the string selection electrode respectively include a ground selection pad, cell pads, and a string selection pad which define a stepped structure in the second region of the substrate, a plurality of dummy pillars penetrating each of the cell pads and a portion of the electrode structure under each of the cell pads, and a cell contact plug electrically connected to each of the cell pads, wherein each of the dummy pillars penetrates a boundary between adjacent cell pads, and wherein the adjacent cell pads share the dummy pillars.

A semiconductor memory device including a first electrode layer provided on a conductive layer; a second electrode layer provided between the conductive layer and the first electrode layer; a first insulating layer provided between the first electrode layer and the second electrode layer; and a pillar layer extending through the first electrode, the second electrode and the first insulating layer in a first direction directed from the conductive layer to the first electrode layer. The pillar layer includes a first portion extending through the first insulating layer and a second portion extending through the second electrode layer. The pillar layer has a first width in a second direction along a surface of the conductive layer at a periphery of the first portion, and a second width in the second direction at a periphery of the second portion. The second width is wider than the first width.

Some embodiments include an integrated structure having stacked conductive levels. At least some of the conductive levels are wordline levels and include control gate regions of memory cells. One of the conductive levels is a vertically outermost conductive level along an edge of the stack. Vertically-extending channel material is along the conductive levels. Some of the channel material extends along the memory cells. An extension region of the channel material is vertically outward of the vertically outermost conductive level. A charge-storage structure has a first region directly between the vertically outermost conductive level and the channel material, and has a second region which extends vertically outward of the vertically outermost conductive level and is along the extension region of the channel material.