An embodiment of a method of integration of a non-volatile memory device into a logic MOS flow is described. Generally, the method includes: forming a pad dielectric layer of a MOS device above a first region of a substrate; forming a channel of the memory device from a thin film of semiconducting material overlying a surface above a second region of the substrate, the channel connecting a source and drain of the memory device; forming a patterned dielectric stack overlying the channel above the second region, the patterned dielectric stack comprising a tunnel layer, a charge-trapping layer, and a sacrificial top layer; simultaneously removing the sacrificial top layer from the second region of the substrate, and the pad dielectric layer from the first region of the substrate; and simultaneously forming a gate dielectric layer above the first region of the substrate and a blocking dielectric layer above the charge-trapping layer.

A non-volatile memory device includes a substrate having a cell array region and an extension region. A mold structure includes a plurality of gate electrodes and a plurality of mold insulating layers alternately stacked on the substrate such that the mold structure has a step shape that steps downwardly in the extension region in a direction away from the cell array region. A channel structure penetrates through the mold structure in the cell array region, and a cell contact structure penetrates through the mold structure in the extension region. A portion of the cell contact structure is in contact with a portion of an uppermost one of the gate electrodes. The cell contact structure includes a first portion in contact with a side surface of the uppermost one of the gate electrodes and a second portion in contact with a top surface of the uppermost one of the gate electrodes. A width of the first portion is smaller than a width of the second portion.

A non-volatile memory device includes a substrate having a cell array region and an extension region. A mold structure includes a plurality of gate electrodes and a plurality of mold insulating layers alternately stacked on the substrate such that the mold structure has a step shape that steps downwardly in the extension region in a direction away from the cell array region. A channel structure penetrates through the mold structure in the cell array region, and a cell contact structure penetrates through the mold structure in the extension region. A portion of the cell contact structure is in contact with a portion of an uppermost one of the gate electrodes. The cell contact structure includes a first portion in contact with a side surface of the uppermost one of the gate electrodes and a second portion in contact with a top surface of the uppermost one of the gate electrodes. A width of the first portion is smaller than a width of the second portion.

Methods of forming a capacitor structure might include forming a first and second conductive regions having first and second conductivity types, respectively, in a semiconductor material, forming a dielectric overlying the first and second conductive regions, forming a conductor overlying the dielectric, and patterning the conductor, the dielectric, and the first and second conductive regions to form a first island of the first conductive region, a second island of the first conductive region, an island of the second conductive region, a first portion of the dielectric overlying the first island of the first conductive region separated from a second portion of the dielectric overlying the second island of the first conductive region and the island of the second conductive region, and a first portion of the conductor overlying the first portion of the dielectric separated from a second portion of the conductor overlying the second portion of the dielectric.

A method of forming a microelectronic device includes forming a microelectronic device structure. The microelectronic device structure includes a stack structure comprising insulative structures and electrically conductive structures vertically alternating with the insulative structures, pillar structures extending vertically through the stack structure, an etch stop material vertically overlaying the stack structure, and a first dielectric material vertically overlying the etch stop material. The method further includes removing portions of the first dielectric material, the etch stop material, and an upper region of the stack structure to form a trench interposed between horizontally neighboring groups of the pillar structures, forming a liner material within the trench, and substantially filling a remaining portion of the trench with a second dielectric material to form a dielectric barrier structure.

A method of forming a microelectronic device includes forming a microelectronic device structure. The microelectronic device structure includes a stack structure comprising insulative structures and electrically conductive structures vertically alternating with the insulative structures, pillar structures extending vertically through the stack structure, an etch stop material vertically overlaying the stack structure, and a first dielectric material vertically overlying the etch stop material. The method further includes removing portions of the first dielectric material, the etch stop material, and an upper region of the stack structure to form a trench interposed between horizontally neighboring groups of the pillar structures, forming a liner material within the trench, and substantially filling a remaining portion of the trench with a second dielectric material to form a dielectric barrier structure.

Embodiments of three-dimensional (3D) memory devices having through stair contacts (TSCs) and methods for forming the same are disclosed. In an example, a 3D memory device includes a memory stack and a TSC. The memory stack includes a plurality of interleaved conductive layers and dielectric layers. Edges of the interleaved conductive layers and dielectric layers define a staircase structure on a side of the memory stack. The TSC extends vertically through the staircase structure of the memory stack. The TSC includes a conductor layer and a spacer circumscribing the conductor layer.

Embodiments of three-dimensional (3D) memory devices having through stair contacts (TSCs) and methods for forming the same are disclosed. In an example, a 3D memory device includes a memory stack and a TSC. The memory stack includes a plurality of interleaved conductive layers and dielectric layers. Edges of the interleaved conductive layers and dielectric layers define a staircase structure on a side of the memory stack. The TSC extends vertically through the staircase structure of the memory stack. The TSC includes a conductor layer and a spacer circumscribing the conductor layer.

Some embodiments include an integrated assembly having a first memory region, a second memory region, and an intermediate region between the first and second memory regions. The intermediate region has a first edge proximate the first memory region and has a second edge proximate the second memory region. Channel-material-pillars are arranged within the first and second memory regions. Conductive posts are arranged within the intermediate region. Doped-semiconductor-material is within the intermediate region and is configured as a substantially H-shaped structure having a first leg region along the first edge, a second leg region along the second edge, and a belt region adjacent the panel. Some embodiments include methods of forming integrated assemblies.

Some embodiments include an integrated assembly having a first memory region, a second memory region, and an intermediate region between the first and second memory regions. The intermediate region has a first edge proximate the first memory region and has a second edge proximate the second memory region. Channel-material-pillars are arranged within the first and second memory regions. Conductive posts are arranged within the intermediate region. Doped-semiconductor-material is within the intermediate region and is configured as a substantially H-shaped structure having a first leg region along the first edge, a second leg region along the second edge, and a belt region adjacent the panel. Some embodiments include methods of forming integrated assemblies.