Some embodiments include a memory cell having charge-trapping-material between a semiconductor channel material and a gating region. The charge-trapping-material includes silicon, nitrogen and trap-enhancing-additive. The trap-enhancing-additive includes one or more of carbon, phosphorus, boron and metal. Some embodiments include an integrated assembly having a stack of alternating first and second levels. The first levels include conductive structures and the second levels are insulative. Channel-material-pillars extend through the stack. Charge-trapping-regions are along the channel-material-pillars and are between the channel-material-pillars and the conductive structures. The charge-trapping-regions include a charge-trapping-material which contains silicon, nitrogen and trap-enhancing-additive. The trap-enhancing-additive includes one or more of carbon, phosphorus, boron and metal.

A 3D memory array includes a row of stacks, each stack having alternating gate strips and dielectric strips. Dielectric plugs are disposed between the stacks and define cell areas. A data storage film and a channel film are disposed adjacent the stacks on the sides of the cell areas. The middles of the cell areas are filled with an intracell dielectric. Source lines and drain lines form vias through the intracell dielectric. The source lines and the drain lines are each provided with a bulge toward the interior of the cell area. The bulges increase the areas of the source line and the drain line without reducing the channel lengths. In some of these teachings, the areas of the source lines and the drain lines are increased by restricting the data storage film or the channel layer to the sides of the cell areas adjacent the stacks.

A memory device may include an electrode structure including a plurality of electrode layers and a plurality of interlayer dielectric layers that are alternately stacked on a substrate; a trench in the electrode structure, and having an upper sidewall, a lower sidewall and a horizontal portion that couples the upper sidewall to the lower sidewall and that is parallel to a top surface of the substrate; a dielectric layer in the trench; and a slimming hole in the electrode structure having a sidewall of the trench and a region of the dielectric layer, and having a bottom surface disposed on an electrode layer on which the horizontal portion of the trench is positioned.

A memory device may include an electrode structure including a plurality of electrode layers and a plurality of interlayer dielectric layers that are alternately stacked on a substrate; a trench in the electrode structure, and having an upper sidewall, a lower sidewall and a horizontal portion that couples the upper sidewall to the lower sidewall and that is parallel to a top surface of the substrate; a dielectric layer in the trench; and a slimming hole in the electrode structure having a sidewall of the trench and a region of the dielectric layer, and having a bottom surface disposed on an electrode layer on which the horizontal portion of the trench is positioned.

A method for manufacturing a cured product pattern of a curable composition includes the steps of, in sequence, depositing a droplet of the curable composition onto a substrate; bringing a mold having an uneven pattern formed in a surface thereof into contact with the curable composition; curing the curable composition; and releasing a cured product of the curable composition from the mold. The mold has a recess having a bottom surface and a stair structure arranged to form an opening surface that becomes wider from the bottom surface toward the surface of the mold. In the contact step, the curable composition comes into contact with the stair portion after a top of the droplet comes into contact with the bottom surface.

A method for manufacturing a cured product pattern of a curable composition includes the steps of, in sequence, depositing a droplet of the curable composition onto a substrate; bringing a mold having an uneven pattern formed in a surface thereof into contact with the curable composition; curing the curable composition; and releasing a cured product of the curable composition from the mold. The mold has a recess having a bottom surface and a stair structure arranged to form an opening surface that becomes wider from the bottom surface toward the surface of the mold. In the contact step, the curable composition comes into contact with the stair portion after a top of the droplet comes into contact with the bottom surface.

A semiconductor device, the device including: a first level including control circuits, where the control circuits include a plurality of first transistors and a plurality of metal layers; and a memory level disposed on top of the first level, where the memory level includes an array of memory cells, where each of the memory cells includes at least one second transistor, where the control circuits control access to the array of memory cells, where the first level is bonded to the memory level, where the bonded includes oxide to oxide bonding regions and a plurality of metal to metal bonding regions, and where at least a portion of the array of memory cells is disposed directly above at least one of the plurality of metal to metal bonding regions.

A method for forming a memory device includes providing an initial semiconductor structure, including a base substrate; a first sacrificial layer formed on the base substrate; a stack structure, disposed on the first sacrificial layer; a plurality of channels, formed through the stack structure and the first sacrificial layer; and a gate-line trench, formed through the stack structure and exposing the first sacrificial layer. The method also includes forming at least one protective layer on the sidewalls of the gate-line trench; removing the first sacrificial layer to expose a portion of each of the plurality of channels and the surfaces of the base substrate, using the at least one protective layer as an etch mask; and forming an epitaxial layer on the exposed surfaces of the base substrate and the plurality of channels.

A semiconductor device includes a first connection pattern; a bit line disposed over the first connection pattern in a vertical direction; and a bit-line contact pad, disposed in a first layer between the bit line and the first connection pattern to electrically couple the bit line to the first connection pattern, and formed as an island when viewed along the vertical direction. A predetermined number of the bit-line contact pads are spaced apart from each other by a predetermined distance in a first direction, when viewed along the vertical direction.

A semiconductor device includes a first connection pattern; a bit line disposed over the first connection pattern in a vertical direction; and a bit-line contact pad, disposed in a first layer between the bit line and the first connection pattern to electrically couple the bit line to the first connection pattern, and formed as an island when viewed along the vertical direction. A predetermined number of the bit-line contact pads are spaced apart from each other by a predetermined distance in a first direction, when viewed along the vertical direction.