A 3D semiconductor device including: a first level including a first single crystal layer, the first level including a plurality of first transistors and at least one first metal layer, where the at least one first metal layer overlays the first single crystal layer, and where the at least one first metal layer includes interconnects between the first transistors forming first control circuits; a second metal layer overlaying the at least one first metal layer; a second level overlaying the second metal layer, the second level including a plurality of second transistors; a third level overlaying the second level, the third level including a plurality of third transistors, where the second level includes a plurality of first memory cells, the first memory cells each including at least one of the second transistors, where the third level includes second memory cells, the second memory cells each including third transistors.

A semiconductor device includes: a first substrate; a second substrate including first and second regions; a stack structure in the first region and extending from the first region into the second region, the stack structure including interlayer insulating layers and gate layers, wherein the gate layers include gate pads having a step shape in the second region; a capping insulating layer at least partially covering the stack structure; an upper insulating layer on the stack structure and the capping insulating layer; a peripheral contact structure including a plurality of through-vias contacting the second substrate and spaced apart from the gate layers, and a peripheral contact pattern on the plurality of through-vias and connecting at least a portion of the plurality of through-vias to each other; a memory vertical structure; a support vertical structure; and a gate contact plug on the gate pads to be electrically connected to the gate pads.

Disclosed is 3D flash memory comprises a gate stack structure, an annular channel pillar, a first source/drain pillar, a second source/drain pillar and a charge storage structure. The gate stack structure is disposed on a dielectric base, and comprising a plurality of gate layers electrically insulated from each other. The annular channel pillar is disposed on the dielectric base and penetrating through the gate stack structure. The first source/drain pillar and the second source/drain pillar, disposed on the dielectric base, located within the annular channel pillar and penetrating through the gate stack structure, wherein the first source/drain pillar and the second source/drain pillar are separated from each other and are each connected to the annular channel pillar. The charge storage structure is disposed between each of the plurality of gate layers and the annular channel pillar. The first source/drain pillar and the second source/drain pillar are P-type doped.

A three-dimensional memory device includes a first alternating stack of first insulating layers and first electrically conductive layers located over a semiconductor material layer, an inter-tier dielectric layer, and a second alternating stack of second insulating layers and second electrically conductive layers located over the inter-tier dielectric layer. A memory opening vertically extends through the second alternating stack, the inter-tier dielectric layer, and the first alternating stack. A memory opening fill structure is located in the memory opening, and includes a first vertical semiconductor channel, a second vertical semiconductor channel, and an inter-tier doped region located between the first and the second semiconductor channel, and providing a first p-n junction with the first vertical semiconductor channel and providing a second p-n junction with the second vertical semiconductor channel.

A three-dimensional memory device includes a first alternating stack of first insulating layers and first electrically conductive layers located over a semiconductor material layer, an inter-tier dielectric layer, and a second alternating stack of second insulating layers and second electrically conductive layers located over the inter-tier dielectric layer. A memory opening vertically extends through the second alternating stack, the inter-tier dielectric layer, and the first alternating stack. A memory opening fill structure is located in the memory opening, and includes a first vertical semiconductor channel, a second vertical semiconductor channel, and an inter-tier doped region located between the first and the second semiconductor channel, and providing a first p-n junction with the first vertical semiconductor channel and providing a second p-n junction with the second vertical semiconductor channel.

Disclosed are approaches for 3D NAND structure fabrication. One method may include providing a stack of layers comprising a first and second plurality of layers, and forming a plurality of trenches in the stack of layers, wherein each of the trenches includes a tiered sidewall. A first trench may be formed to a first depth, and a second trench may be formed to a second depth, which is greater than the first depth. The method may further include forming a liner within the trenches, wherein the liner is deposited at a non-zero angle of inclination relative to a normal extending perpendicular from the top surface of the stack of layers. The liner may have a first thickness along the tiered sidewall of the first trench and a second thickness along the tiered sidewall of the second trench, wherein the first thickness is greater than the second thickness.

A memory structure and a manufacturing method for the same are provided. The memory structure includes a charge trapping layer, a first silicon oxynitride tunneling film and a second silicon oxynitride tunneling film. The first silicon oxynitride tunneling film is between the charge trapping layer and the second silicon oxynitride tunneling film. A first atom concentration ratio of a concentration of a nitrogen atom to a total concentration of an oxygen atom and the nitrogen atom of the first silicon oxynitride tunneling film is 10% to 50%. A second atom concentration ratio of a concentration of a nitrogen atom to a total concentration of an oxygen atom and the nitrogen atom of the second silicon oxynitride tunneling film is 1% to 15%. The concentration of the nitrogen atom of the second silicon oxynitride tunneling film is lower than that of the first silicon oxynitride tunneling film.

A memory structure and a manufacturing method for the same are provided. The memory structure includes a charge trapping layer, a first silicon oxynitride tunneling film and a second silicon oxynitride tunneling film. The first silicon oxynitride tunneling film is between the charge trapping layer and the second silicon oxynitride tunneling film. A first atom concentration ratio of a concentration of a nitrogen atom to a total concentration of an oxygen atom and the nitrogen atom of the first silicon oxynitride tunneling film is 10% to 50%. A second atom concentration ratio of a concentration of a nitrogen atom to a total concentration of an oxygen atom and the nitrogen atom of the second silicon oxynitride tunneling film is 1% to 15%. The concentration of the nitrogen atom of the second silicon oxynitride tunneling film is lower than that of the first silicon oxynitride tunneling film.

According to one embodiment, a semiconductor memory device includes a first stacked body in which a plurality of first conductive layers are stacked at intervals in a first direction above a semiconductor substrate; a second stacked body in which a plurality of second conductive layers are stacked at intervals in the first direction above the semiconductor substrate; and a first slit extending in a second direction perpendicular to the first direction, the first slit isolating the first stacked body and the second stacked body in a third direction perpendicular to the first and second directions.

Some embodiments include apparatuses and methods of forming the apparatuses. One of the apparatuses includes a memory cell included in a memory cell string; the memory cell including charge storage structure and channel structure separated from the charge storage structure by a dielectric structure; a first control gate associated with the memory cell and located on a first side of the charge storage structure and a first side of the channel structure; and a second control gate associated with the memory cell and electrically separated from the first control gate, the second control gate located on a second side of the charge storage structure and a second side of the channel structure.