A three-dimensional memory device includes a first electrode structure and a second electrode structure extending in a first direction, being adjacent to each other in a second direction intersecting with the first direction, and each including a plurality of electrode layers and a plurality of interlayer dielectric layers which are alternately stacked on a source plate; a plurality of first slimming holes formed in the first electrode structure to expose pad regions of the electrode layers of the first electrode structure, and arranged in the first direction; and a plurality of second slimming holes formed in the second electrode structure to expose pad regions of the electrode layers of the second electrode structure, and arranged in the first direction, wherein a first slimming hole and a second slimming hole which are adjacent in the second direction have different depths.

A three-dimensional memory device includes a first electrode structure and a second electrode structure extending in a first direction, being adjacent to each other in a second direction intersecting with the first direction, and each including a plurality of electrode layers and a plurality of interlayer dielectric layers which are alternately stacked on a source plate; a plurality of first slimming holes formed in the first electrode structure to expose pad regions of the electrode layers of the first electrode structure, and arranged in the first direction; and a plurality of second slimming holes formed in the second electrode structure to expose pad regions of the electrode layers of the second electrode structure, and arranged in the first direction, wherein a first slimming hole and a second slimming hole which are adjacent in the second direction have different depths.

Disclosed are semiconductor devices and electronic systems including the same. The semiconductor device may include a stack structure extending in a first direction and including gate electrodes vertically stacked on a substrate, selection structures horizontally spaced apart on the stack structure, an upper isolation structure between the selection structure and extending in the first direction on the stack structure, and vertical structures penetrating the stack structure and the selection structures. The vertical structures include first vertical structures arranged along the first direction and penetrating portions of the upper isolation structure. Each selection structure includes a selection gate electrode and a horizontal dielectric pattern that surrounds top, bottom, and sidewall surfaces of the selection gate electrode. Each selection gate electrode includes a line part extending in the first direction, and an electrode part vertically protruding from the line part and surrounding at least a portion of each first vertical structure.

Semiconductor devices are provided. The semiconductor devices may include a peripheral circuit structure, a memory cell block arranged on the peripheral circuit structure and including strings, each of which includes a lower select transistor, memory cell transistors, and an upper select transistor connected in series and stacked in a vertical direction, and bit lines on the memory cell block. The bit lines may include a first bit line electrically connected to first to third strings of the strings. The lower select transistors of the first to third strings include first to third lower select gate electrodes, respectively. The second lower select gate electrode may be arranged at a different vertical level from the first lower select gate electrode, and the third lower select gate electrode may be arranged at the same vertical level as the first lower select gate electrode.

Disclosed are a three-dimensional semiconductor memory device and an electronic system including the same. A semiconductor device includes a substrate, a cell array structure including a plurality of electrodes stacked on the substrate, a vertical channel structure that penetrates the cell array structure and is connected to the substrate, a conductive pad in an upper portion of the vertical channel structure, an interlayer insulating layer on the cell array structure, a bit line on the cell array structure, a bit line contact electrically connecting the bit line to the conductive pad, and a first stress release layer between the cell array structure and the bit line on a top surface of the interlayer insulating layer. The first stress release layer includes organosilicon polymer, and a carbon concentration of the first stress release layer is higher than that of the interlayer insulating layer.

Disclosed are a three-dimensional semiconductor memory device and an electronic system including the same. A semiconductor device includes a substrate, a cell array structure including a plurality of electrodes stacked on the substrate, a vertical channel structure that penetrates the cell array structure and is connected to the substrate, a conductive pad in an upper portion of the vertical channel structure, an interlayer insulating layer on the cell array structure, a bit line on the cell array structure, a bit line contact electrically connecting the bit line to the conductive pad, and a first stress release layer between the cell array structure and the bit line on a top surface of the interlayer insulating layer. The first stress release layer includes organosilicon polymer, and a carbon concentration of the first stress release layer is higher than that of the interlayer insulating layer.

Vertical wordline driver structures and methods. The vertical wordline driver comprises a transistor that is used to drive a wordline in a three-dimensional 3D memory structure. A vertical transistor structure is formed in a semiconductor substrate comprising a gate all around (GAA) structure or a double-gate structure including a gate oxide, an amorphous IGZO (Indium Gallium Zinc Oxide) channel, adjacent to the gate oxide, and a liner adjacent to the amorphous IGZO channel. The GAA structure may comprise a conical frustrum shape or a cylindrical shape with straight walls. The double-gate structure may have straight or angled walls. An outer wall of the gate oxide is in contact with a polysilicon gate layer. An upper and lower contact is electrically coupled to the amorphous IGZO channel.

Vertical wordline driver structures and methods. The vertical wordline driver comprises a transistor that is used to drive a wordline in a three-dimensional 3D memory structure. A vertical transistor structure is formed in a semiconductor substrate comprising a gate all around (GAA) structure or a double-gate structure including a gate oxide, an amorphous IGZO (Indium Gallium Zinc Oxide) channel, adjacent to the gate oxide, and a liner adjacent to the amorphous IGZO channel. The GAA structure may comprise a conical frustrum shape or a cylindrical shape with straight walls. The double-gate structure may have straight or angled walls. An outer wall of the gate oxide is in contact with a polysilicon gate layer. An upper and lower contact is electrically coupled to the amorphous IGZO channel.

A 3D-NAND memory includes a transistor formed in a first side of a periphery circuit substrate, a memory cell stack formed over a first side of a cell array substrate, and a first connection structure formed over an opposing second side of the cell array substrate. The memory cell stack includes a doped region formed in the first side of the cell array substrate and coupled to the first connection structure through a first VIA, a common source structure that extends from the doped region toward the first side of the periphery circuit substrate, and a second connection structure that is positioned over and coupled to the common source structure. The first side of the cell array substrate and the first side of the periphery circuit substrate are aligned facing each other so that the transistor is coupled to the second connection structure.

Some embodiments include a method of forming a conductive structure. A metal-containing conductive material is formed over a supporting substrate. A surface of the metal-containing conductive material is exposed to at least one radical form of hydrogen and to at least one oxidant. The exposure alters at least a portion of the metal-containing conductive material to thereby form at least a portion of the conductive structure. Some embodiments include a conductive structure which has a metal-containing conductive material with a first region adjacent to a second region. The first region has a greater concentration of one or both of fluorine and boron relative to the second region.