Abstract: According to one embodiment, a method for manufacturing a semiconductor device is disclosed. The method includes forming a stacked body alternately stacked with a plurality of members and a plurality of intermediate bodies having materials different from materials of the plurality of members, processing an end portion of at least two layers of the plurality of members sequentially in a stacking direction of the stacked body, and forming a step-wise step stacked with the plurality of members and the plurality of intermediate bodies, forming a plurality of side wall films contacting the step and making the end portion of the plurality of members in a step-wise. The making the end portion of the plurality of members in a step-wise includes retreating a portion of the plurality of members, the portion separated from the plurality of side wall films and exposed from the stacked body.

Abstract: A method for manufacturing includes forming a first insulating film on a substrate, forming first to third portions in the first insulating film, forming a second insulating film on the first insulating film, removing a part of the second portion, a portion including a region directly above the part of the second portion of the second insulating film, and at least a part of a portion including a region directly above the other part of the second portion of the second insulating film, and forming a first stacked body, forming a stacked film by alternately stacking third and fourth insulating films, and forming a stacked structure by processing a remaining part of the stacked film into a stepped pattern forming steps at each of the third insulating films. A depression is formed on the region directly above the third portion in an upper surface of the second insulating film.

Abstract: A semiconductor memory device according to an embodiment includes a memory cell array that includes memory cells and a plurality of first conducting layers. The memory cells are arrayed in a three-dimensional manner. The first conducting layers are connected to the memory cells and are arrayed in a laminating direction. Stepped wiring portion includes a plurality of second conducting layers. The plurality of second conducting layers connect the first conducting layers and external circuits. At least one of the plurality of second conducting layers includes a contact formation area on a top surface thereof in the stepped wiring portion positioned on the first side portion side. Other ones of the plurality of second conducting layers includes a contact formation area on a top surface thereof in the stepped wiring portion positioned on the second side portion side.

Abstract: According to one embodiment, a method for manufacturing a semiconductor memory device includes forming a stacked body including a plurality of first layers and a plurality of second layers on a substrate. The method includes forming a first slit and a second slit simultaneously by dry-etching the stacked body. The first slit causes a part of the stacked body to have a comb-shaped pattern including a plurality of line parts isolated in a first direction and extending in a second direction. The second slit surrounds the comb-shaped pattern with a closed pattern. The method includes forming a hole in the line parts of the stacked body. The method includes forming a charge storage film and a semiconductor body in the hole.

Abstract: A nonvolatile semiconductor memory device comprises: a memory cell region having a memory cell disposed therein; a peripheral region including a first stepped structure in which an end of a lower first layer is further from the memory cell region than is an end of an upper first layer; and a second stepped structure disposed on the first stepped structure, in which an end of a lower third layer is disposed further from the memory cell region than is an end of an upper third layer, a length in a second direction being shorter than a length in the second direction of the first layer or the second layer contacted by the second stepped structure, and a length in a third direction of the second stepped structure being shorter than a length in the third direction of the first layer or the second layer contacted by the second stepped structure.

Abstract: A nonvolatile semiconductor memory device comprises: a memory cell region having a memory cell disposed therein; a peripheral region including a first stepped structure in which an end of a lower first layer is further from the memory cell region than is an end of an upper first layer; and a second stepped structure disposed on the first stepped structure, in which an end of a lower third layer is disposed further from the memory cell region than is an end of an upper third layer, a length in a second direction being shorter than a length in the second direction of the first layer or the second layer contacted by the second stepped structure, and a length in a third direction of the second stepped structure being shorter than a length in the third direction of the first layer or the second layer contacted by the second stepped structure.

Abstract: A semiconductor memory device according to an embodiment includes a memory cell array configured to have a memory string obtained by connecting first selection transistors, memory transistors, and second selection transistors in series. When three directions crossing each other are set to first, second, and third directions, respectively, the memory cell array has first conductive layers to be control gates of the first selection transistors, second conductive layers to be control gates of the memory transistors, and third conductive layers to be control gates of the second selection transistors, which are laminated in the third direction. Ends of the first conductive layers and ends of the third conductive layers are formed in shapes of steps extending in the first direction and ends of the second conductive layers are formed in shapes of steps extending in both directions of the first direction and the second direction.

Abstract: According to one embodiment, a semiconductor memory device includes a stacked body, a selection gate electrode, a semiconductor pillar, a first insulating member, a second insulating member, a third insulating member. The stacked body is provided on the substrate. The selection gate electrode is provided on the stacked body. The first insulating member divides the stacked body in a first direction. The second insulating member is provided in an area directly above the first insulating member and dividing the selection gate electrode in the first direction. The third insulating member is provided in a region other than the area directly above the first insulating member and dividing the selection gate electrode in the first direction. An average width of the second insulating member in the first direction is larger than an average width of the third insulating member in the first direction.

Abstract: According to one embodiment, a method for manufacturing a semiconductor memory device includes forming a stacked body including a plurality of first layers and a plurality of second layers on a substrate. The method includes forming a first slit and a second slit simultaneously by dry-etching the stacked body. The first slit causes a part of the stacked body to have a comb-shaped pattern including a plurality of line parts isolated in a first direction and extending in a second direction. The second slit surrounds the comb-shaped pattern with a closed pattern. The method includes forming a hole in the line parts of the stacked body. The method includes forming a charge storage film and a semiconductor body in the hole.

Abstract: According to an embodiment, a method for fabricating a pattern includes forming a mask covering a first layer, and a second layer selectively provided on the first layer, and forming a groove dividing the first layer and the second layer using the mask. The mask includes a first portion formed on a region of the first layer on a first side of the second layer, a second portion formed on a region of the first layer on a second side of the second layer opposite to the first side, first extending parts extending over the second layer from the first portion toward the second portion, and second extending parts extending over the second layer from the second portion toward the first portion. Each of the second extending parts is located between the first extending parts adjacent to each other.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device includes: a semiconductor substrate; a multilayer interconnection structure unit; a stacked body; a channel body layer; a memory film; a contact electrode. The multilayer interconnection structure unit is provided on the semiconductor substrate, and the multilayer interconnection structure unit has interconnections. The stacked body is provided on the multilayer interconnection structure unit, and each of electrode layers and each of first insulating layers are alternately arranged in the stacked body. The channel body layer extends in the stacked body in a stacking direction of the stacked body. The memory film is provided between the channel body layer and each of the electrode layers. And the contact electrode extends in the stacked body in the stacking direction, and the contact electrode electrically connects any one of the electrode layers and any one of the interconnection layers.

Abstract: In one embodiment, a method of manufacturing a semiconductor device includes forming a first mask layer on a workpiece layer. The method further includes forming a concave portion in the workpiece layer by first etching using the first mask layer. The method further includes forming a second mask layer on the workpiece layer in which the concave portion is formed. The method further includes processing the concave portion of the workpiece layer by second etching using the second mask layer.

Abstract: According to one embodiment, a method for manufacturing a semiconductor device includes forming a plurality of insulating isolation sections provided so as to extend in a first direction, isolate the stacked body in a second direction, and have a projection projecting from the stacked body. Each insulating isolation section has a side wall including recessed sections and projected sections repeated along the first direction. The method includes forming a sidewall film on a side wall of the projection of the insulating isolation section, and forming a plurality of first holes surrounded by the sidewall film and isolated by the sidewall film in the first direction, between the plurality of insulating isolation sections. The method includes forming a second hole in the stacked body provided under the first hole by etching with the insulating isolation section and the sidewall film used as a mask.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device includes: first and second stacked bodies, first and second semiconductor pillars, a connection portion, a memory film, and a partitioning insulating layer. The stacked bodes include electrode films stacked along a first axis and an inter-electrode insulating film provided between the electrode films. Through-holes are provided in the stacked bodies. The semiconductor pillars are filled into the through-holes. The connection portion electrically connects the semiconductor pillars. The memory film is provided between the semiconductor pillars and the electrode films. The partitioning insulating layer partitions the first and second electrode films. A side surface of the first through-hole on the partitioning insulating layer side and a side surface of the second through-hole on the partitioning insulating layer side have a portion parallel to a plane orthogonal to a second axis from the first stacked body to the second stacked body.

Abstract: According to an embodiment, a solid state storage device includes a first gate; a plurality of conductive layers having insulating layers therebetween, one of the insulating layers located on the first gate, an interconnection region extending inwardly of the first gate, a first semiconductor layer extending through the plurality of conductive layers and insulating layers, a second semiconductor layer extending through the plurality of conductive layers and insulating layers; a third semiconductor layer extending through the interconnection region and electrically connecting the first and second semiconductor layers, and an insulator extending through the plurality of conductive layers and insulating layers at a location intermediate of the first and second semiconductor layers, and also extending inwardly of the interconnection region.

Abstract: According to an embodiment, a method for fabricating a pattern includes forming a mask covering a first layer, and a second layer selectively provided on the first layer, and forming a groove dividing the first layer and the second layer using the mask. The mask includes a first portion formed on a region of the first layer on a first side of the second layer, a second portion formed on a region of the first layer on a second side of the second layer opposite to the first side, first extending parts extending over the second layer from the first portion toward the second portion, and second extending parts extending over the second layer from the second portion toward the first portion. Each of the second extending parts is located between the first extending parts adjacent to each other.

Abstract: According to one embodiment, a method for manufacturing a semiconductor device includes forming a stacked body on a substrate. The stacked body includes a plurality of first conductive layers including a metallic element as a main component and a plurality of second conductive layers including a metallic element as a main component provided respectively between the first conductive layers. The method includes making a hole to pierce the stacked body. The method includes making a slit to divide the stacked body. The method includes making a gap between the first conductive layers by removing the second conductive layers by etching via the slit or the hole. The method includes forming a memory film including a charge storage film at a side wall of the hole. The method includes forming a channel body on an inner side of the memory film inside the hole.

Abstract: A nonvolatile semiconductor storage device includes: a structural body; semiconductor layers; a memory film; a connecting member; and a conductive member. The structural body is provided above a memory region of a substrate including the memory region and a non-memory region, and includes electrode films stacked along a first axis perpendicular to a major surface of the substrate. The semiconductor layers penetrate through the structural body along the first axis. The memory film is provided between the electrode films and the semiconductor layer. The connecting member is provided between the substrate and the structural body and connected to respective end portions of two adjacent ones of the semiconductor layers. The conductive member is provided between the substrate and the connecting member, extends from the memory region to the non-memory region, includes a recess provided above the non-memory region, and includes a first silicide portion provided in the recess.

Abstract: According to one embodiment, a method is disclosed for manufacturing nonvolatile semiconductor memory device including forming a stacked body by alternately stacking an electrode layer and a layer-to-be-etched, and forming an oxidized layer between the layer-to-be-etched provided at least in any side of an upper side and a lower side of the electrode layer and the electrode layer. The method can include forming a groove which passes through the stacked body. The method can include embedding an insulating body within the groove. The method can include forming a hole which passes through the stacked body. The method can include selectively removing the layer-to-be-etched via the hole. The method can include forming a charge storage layer in an inner side of the hole. The method can include forming a channel body layer in an inner side of the charge storage layer.

Abstract: According to one embodiment, a method for manufacturing a semiconductor device includes forming a stacked body on a substrate. The stacked body includes a plurality of first conductive layers including a metallic element as a main component and a plurality of second conductive layers including a metallic element as a main component provided respectively between the first conductive layers. The method includes making a hole to pierce the stacked body. The method includes making a slit to divide the stacked body. The method includes making a gap between the first conductive layers by removing the second conductive layers by etching via the slit or the hole. The method includes forming a memory film including a charge storage film at a side wall of the hole. The method includes forming a channel body on an inner side of the memory film inside the hole.