A semiconductor device includes a substrate, an active structure, a memory structure, and a first conductive line. The active structure is disposed on the substrate. The memory structure is disposed over the active structure, and has a lower surface and an upper surface opposite to each other. The memory structure includes a deep via disposed in the memory structure, and extends in an upward direction from the lower surface to terminate at the upper surface. The first conductive line is disposed above the upper surface of the memory structure, and extends in a first lengthwise direction transverse to the upward direction. The first conductive line is electrically connected to the active structure through the deep via. A method for manufacturing the semiconductor device is also disclosed.

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.

Provided is a three-dimensional (3D) memory device including: a substrate, a stack structure, and a plurality of barrier structures. The stack structure is disposed on the substrate. The stack structure includes a plurality of dielectric layers and a plurality of gate layers stacked alternately. The plurality of barrier structures respectively wrap surfaces of the plurality of gate layers. Each barrier structure includes a first barrier layer and a second barrier layer. The first barrier layer continuously covers a top surface, a bottom surface and a first sidewall of a corresponding gate layer. The second barrier layer covers a second sidewall of the corresponding gate layer opposite to the first sidewall, and connects the first barrier layer. The second barrier layer has a thickness greater than a thickness of the first barrier layer. A method of forming a 3D memory device is also provided.

Provided is a three-dimensional (3D) memory device including: a substrate, a stack structure, and a plurality of barrier structures. The stack structure is disposed on the substrate. The stack structure includes a plurality of dielectric layers and a plurality of gate layers stacked alternately. The plurality of barrier structures respectively wrap surfaces of the plurality of gate layers. Each barrier structure includes a first barrier layer and a second barrier layer. The first barrier layer continuously covers a top surface, a bottom surface and a first sidewall of a corresponding gate layer. The second barrier layer covers a second sidewall of the corresponding gate layer opposite to the first sidewall, and connects the first barrier layer. The second barrier layer has a thickness greater than a thickness of the first barrier layer. A method of forming a 3D memory device is also provided.

A semiconductor device includes a substrate having a first region and a second region, a first stack structure in the first region, a first channel structure penetrating through the first stack structure and in contact with the substrate, and a second stack structure on the first stack structure and the first channel structure. The device includes a second channel structure penetrating through the second stack structure and connected to the first channel structure, a first molding structure in the second region, a first alignment structure penetrating through the first molding structure and in contact with the substrate, and a second molding structure on the first molding structure and the first alignment structure. The device includes a second alignment structure penetrating through the second molding structure and connected to the first alignment structure, and a protective layer between the first molding structure and the second molding structure.

A semiconductor device includes a substrate having a first region and a second region, a first stack structure in the first region, a first channel structure penetrating through the first stack structure and in contact with the substrate, and a second stack structure on the first stack structure and the first channel structure. The device includes a second channel structure penetrating through the second stack structure and connected to the first channel structure, a first molding structure in the second region, a first alignment structure penetrating through the first molding structure and in contact with the substrate, and a second molding structure on the first molding structure and the first alignment structure. The device includes a second alignment structure penetrating through the second molding structure and connected to the first alignment structure, and a protective layer between the first molding structure and the second molding structure.

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 non-volatile memory device includes a memory cell region and a peripheral circuit region below the memory cell region in a vertical direction. The memory cell region includes an upper substrate, channel structures extending in the vertical direction, and a first upper metal line extending in a first direction. The peripheral circuit region includes a first lower metal line extending in a second direction and a first via structure on the first lower metal line and a second via structure on the first lower metal line, a top surface of the second via being in contact with the upper substrate. The memory cell region further includes a first through-hole via structure passing through the upper substrate and the first via structure, and electrically connecting the first upper metal line to the first lower metal line; and the first upper metal line is electrically connected to the upper substrate through the first through-hole via structure, the first lower metal line, and the second via structure.