A semiconductor device includes a stacked structure including a first region in which conductive layers and the insulating layers are stacked alternately with each other, and a second region in which sacrificial layers and the insulating layers are stacked alternately with each other, a first slit structure located at a boundary between the first region and the second region and including a first through portion passing through the stacked structure and first protrusions extending from a sidewall of the first through portion, a second slit structure located at the boundary and including a second through portion passing through the stacked structure and second protrusions extending from a sidewall of the second through portion and coupled to the first protrusions, a circuit located under the stacked structure, and a contact plug passing through the second region of the stacked structure and electrically connected to the circuit.

A method for producing a 3D semiconductor device including: providing a first level including a first single crystal layer; forming peripheral circuitry in and/or on the first level, and includes first single crystal transistors; forming a first metal layer on top of the first level; forming a second metal layer on top of the first metal layer; forming second level disposed on top of the second metal layer; performing a first lithography step; forming a third level on top of the second level; performing a second lithography step; processing steps to form first memory cells within the second level and second memory cells within the third level, where the plurality of first memory cells include at least one second transistor, and the plurality of second memory cells include at least one third transistor; and deposit a gate electrode for second and third transistors simultaneously.

A staggered memory cell architecture staggers memory cells on opposite sides of a shared bit line preserves memory cell density, while increasing the distance between such memory cells, thereby reducing the possibility of a disturb. In one implementation, the memory cells along a first side of a shared bit line are connected to a set of global word lines provided underneath the memory structure, while the memory cells on the other side of the shared bit line—which are staggered relative to the memory cells on the first side—are connected to global word lines above the memory structure.

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.

Joint opening structures of 3D memory devices and fabricating method are provided. A joint opening structure comprises a first through hole penetrating a first stacked layer and a first insulating connection layer, a first channel structure at the bottom of the first through hole, a first functional layer on the sidewall of the first through hole, a second channel structure on the sidewall of the first functional layer, a third channel structure over the first through hole, a second stacked layer on the third channel structure, a second insulating connection layer on the second stacked layer, a second through hole penetrating the second stacked layer and the second insulating connection layer, a second functional layer disposed on the sidewall of the second through hole, a fourth channel structure on the sidewall of the second functional layer, and a fifth channel structure over the second through hole.

A semiconductor storage device includes a memory cell array having a plurality of first conductive layers stacked in a first direction and a plurality of memory cells connected to the plurality of first conductive layers, a wiring layer, and an insulating layer between the memory cell array and the wiring layer and separating the memory cell array and the wiring layer in a second direction intersecting the first direction. The wiring layer includes a plurality of second conductive layers stacked in the first direction, each of the second conductive layers having a corresponding first conductive layer at a same layer, and a contact connected to at least a part of the plurality of second conductive layers and extending in the first direction.

A semiconductor device includes a substrate, a stacked body, a plurality of columnar semiconductors, a semiconductor layer, and a conductive portion. The stacked body is placed above the substrate. The stacked body includes a plurality of conductive layers stacked with an insulating layer placed therebetween. The plurality of columnar semiconductors pass through the stacked body. The semiconductor layer is placed above the substrate. The semiconductor layer is connected to bottoms of the columnar semiconductors. The semiconductor layer has a groove pattern in a region adjacent to the stacked body. The conductive portion fills the groove pattern and is in contact with a side surface of the semiconductor layer in the region. The conductive portion electrically connects the semiconductor layer to the substrate.

A method for producing a 3D memory device, the method including: providing a first level including a first single crystal layer and control circuits; forming at least one second level above the first level; performing a first etch step including etching holes within the second level; forming at least one third level above the at least one second level; performing a second etch step including etching holes within the third level; and performing additional processing steps to form a plurality of first memory cells within the second level and a plurality of second memory cells within the third level, where each of the first memory cells include one first transistor, where each of the second memory cells include one second transistor, where at least one of the first or second transistors has a channel, a source, and a drain having a same doping type.

A method for producing a 3D memory device including: providing a first level including a single crystal layer and control circuits, where the control circuits include a plurality of first transistors; forming at least one second level above the first level; performing a first etch step including etching holes within the second level; performing processing steps to form a plurality of first memory cells within the second level, where each of the first memory cells include one of a plurality of second transistors, where the control circuits include memory peripheral circuits, where at least one first memory cell is at least partially atop a portion of the memory peripheral circuits, and where fabrication processing of the first transistors accounts for a temperature and time associated with processing the second level and the plurality of second transistors by adjusting a process thermal budget of the first level accordingly.

A three-dimensional AND flash memory device includes a stack structure, isolators, channel pillars, source pillars and drain pillars, and charge storage structures. The stack structure is located on a dielectric substrate and includes gate layers and insulating layers alternately stacked with each other. The isolators divide the stack structure into sub-blocks and include walls and slits. The walls include isolation layers and the insulating layers stacked alternately with each other, and the isolation layers are buried in the gate layers. The slits alternate with the walls, and each of the slits extends through the stack structure. The channel pillars extend through the stack structure in each of the sub-blocks. The source pillars and the drain pillars are located in the channel pillars. The charge storage structures are located between the gate layers and the channel pillar.