A semiconductor memory device includes a first source layer, a second source layer on the first source layer, a stack structure over the second source layer, and a common source line penetrating the stack structure. The second source layer includes a protective layer in contact with the common source line and a conductive layer surrounding the protective layer.

Provided is a memory device including a substrate, a stack structure on the substrate, a contact, and a supporting pillar. The stacked structure includes a plurality of conductive layers and a plurality of insulating layers stacked alternately on each other. The contact is connected to one of the plurality of conductive layers of the stack structure. The supporting pillar penetrates the stack structure and is disposed around the contact. The supporting pillar includes a body portion and a plurality of extension portions. The body portion is arranged around a first side of the contact. The plurality of extension portions are located on two sides of the body portion. A length of each of the extension portions is greater than a width of the contact, and one of the extension portions is disposed around a second side of the contact.

A microelectronic device comprises a stack structure comprising vertically alternating conductive structures and insulating structures arranged in tiers, the tiers individually comprising one of the conductive structures and one of the insulating structures, a staircase structure within the stack structure and having steps comprising edges of at least some of the tiers, conductive contact structures on the steps of the staircase structure, support pillar structures laterally offset in at least a first direction from the conductive contact structures and extending through the stack structure, and bridge structures comprising an electrically insulating material extending vertically through at least a portion of the stack structure and between at least some adjacent support pillar structures of the support pillar structures. Related memory devices, electronic systems, and methods are also described.

A method comprising forming a stack precursor comprising alternating first materials and second materials, the first materials and the second materials exhibit different melting points. A portion of the alternating first materials and second materials is removed to form a pillar opening through the alternating first materials and second materials. A sacrificial material is formed in the pillar opening. The first materials are removed to form first spaces between the second materials, the first materials formulated to be in a liquid phase or in a gas phase at a first removal temperature. A conductive material is formed in the first spaces. The second materials are removed to form second spaces between the conductive materials, the second materials formulated to be in a liquid phase or in a gas phase at a second removal temperature. A dielectric material is formed in the second spaces. The sacrificial material is removed from the pillar opening and cell materials are formed in the pillar opening.

Some embodiments include an integrated assembly having a source structure. The source structure includes, in ascending order, a first conductively-doped semiconductor material, one or more first insulative layers, a second conductively-doped semiconductor material, one or more second insulative layers, and a third conductively-doped semiconductor material. The source structure includes blocks extending through the second conductively-doped semiconductor material. Conductive levels are over the source structure. Channel material extends vertically along the conductive levels, and extends into the source structure to be in direct contact with the second conductively-doped semiconductor material. One or more memory cell materials are between the channel material and the conductive levels. Some embodiments include methods of forming integrated assemblies.

A patterned backside stress compensation film having different stress in different sectors is formed on a backside of a substrate to reduce combination warpage of the substrate. The film can be formed by employing a radio frequency electrode assembly including plurality of conductive plates that are biased with different RF power and cause local variations in the plasma employed to deposit the backside film. Alternatively, the film may be deposited with uniform stress, and some of its sectors are irradiated with ultraviolet radiation to change the stress of these irradiated sectors. Yet alternatively, multiple backside deposition processes may be sequentially employed to deposit different backside films to provide a composite backside film having different stresses in different sectors.

A semiconductor device with high storage capacity is provided. The semiconductor device includes first to sixth insulators, first to third conductors, and first to third material layers. The first conductor overlaps with a first insulator and a first material layer. A first region of the first material layer overlaps with a second material layer, a second conductor, a second insulator, and a third insulator. The third material layer is positioned in a region including a second region of the first material layer and top surfaces of the second material layer, the second conductor, the second insulator, and the third insulator; a fourth insulator is positioned over the third material layer; the sixth insulator is positioned over the fourth insulator; and a fifth insulator is positioned over the sixth insulator. The third conductor is positioned over the fifth insulator overlapping with the second region of the first material layer. The first to third material layers include oxide containing indium, an element M (M is aluminum, gallium, tin, or titanium), and zinc.

The disclosed technology generally relates to memory structures, for example for a vertical NAND memory. In one aspect, a memory structure includes a substrate and a layer stack arranged on a surface of the substrate, wherein the layer stack includes one or more conductive material layers alternating with one or more dielectric material layers. The memory structure can also include a trench in the layer stack, wherein the trench is formed through the one or more conductive material layers, and wherein the trench includes inner side walls. The memory structure also includes a programmable material layer arranged in the trench and which covers the inner side walls of the trench. The memory structure further includes an oxide semiconductor layer arranged in the trench over the programmable material layer.

A semiconductor device includes a first substrate; circuit elements on the first substrate; lower interconnection lines electrically connected to the circuit elements; a second substrate on the lower interconnection lines; gate electrodes spaced apart from each other and stacked on the second substrate in a first direction that is perpendicular to an upper surface of the second substrate; channel structures penetrating through the gate electrodes, extending in the first direction, and respectively including a channel layer; through-vias extending in the first direction and electrically connecting at least one of the gate electrodes or the channel structures to the circuit elements; an insulating region surrounding side surfaces of through-vias; and a via pad between the through-vias and at least one of the lower interconnection lines in the first direction and spaced apart from the second substrate in a second direction, parallel to an upper surface of the second substrate.

A three-dimensional semiconductor memory device includes a first substrate, a peripheral circuit structure with peripheral transistors on the first substrate, a second substrate on the peripheral circuit structure, a lower insulating layer in contact with a side surface of the second substrate, a top surface of the lower insulating layer having a concave profile, a first stack on the second substrate, the first stack including repeatedly alternating first interlayer dielectric layers and gate electrodes, and a first mold structure on the lower insulating layer, the first mold structure including repeatedly alternating sacrificial layers and second interlayer dielectric layers, and a top surface of the first mold structure being at a level lower than a topmost surface of the first stack.