A semiconductor memory device includes: a peripheral circuit portion including an interconnection; first and second word line stacks that are spaced apart from each other over the peripheral circuit portion, the first and second word line stacks including word lines, respectively; an alternating stack of dielectric layers that are positioned over the peripheral circuit portion and disposed between the first and second word line stacks; a first contact plug penetrating the alternating stack to be coupled to the interconnection; a second contact plug coupled to the word lines of the first and second word line stacks; a first line-shape supporter between the first word line stack and the alternating stack, and extending vertically from the peripheral circuit portion; and a second line-shape supporter between the second word line stack and the alternating stack, and extending vertically from the peripheral circuit portion.

Methods, systems, and devices for thin film transistor deck selection in a memory device are described. A memory device may include memory arrays arranged in a stack of decks formed over a substrate, and deck selection components distributed among the layers to leverage common substrate-based circuitry. For example, each memory array of the stack may include a set of digit lines of a corresponding deck, and deck selection circuitry operable to couple the set of digit lines with a column decoder that is shared among multiple decks. To access memory cells of a selected memory array on one deck, the deck selection circuitry corresponding to the memory array may each be activated, while the deck selection circuitry corresponding to a non-selected memory array on another deck may be deactivated. The deck selection circuitry, such as transistors, may leverage thin-film manufacturing techniques, such as various techniques for forming vertical transistors.

A semiconductor device including: a first silicon layer including a first single crystal silicon and a plurality of first transistors; a first metal layer disposed over the first silicon layer; a second metal layer disposed over the first metal layer; a third metal layer disposed over the second metal layer; a second level including a plurality of second transistors, the second level disposed over the third metal layer; a fourth metal layer disposed over the second level; a fifth metal layer disposed over the fourth metal layer, a connection path from the fifth metal layer to the second metal layer, where the connection path includes a via disposed through the second level, where the via has a diameter of less than 450 nm, where the fifth metal layer includes a global power distribution grid, and where a typical thickness of the fifth metal layer is greater than a typical thickness of the second metal layer by at least 50%.

Described herein are IC devices that include multilayer memory structures bonded to compute logic using low-temperature oxide bonding to realize high-density three-dimensional (3D) dynamic random-access memory (DRAM). An example device includes a compute die, a multilayer memory structure, and an oxide bonding interface coupling the compute die to the multilayer memory structure. The oxide bonding interface includes metal interconnects and an oxide material surrounding the metal interconnects and bonding the compute die to the memory structure.

Embodiments of the present disclosure are based on recognition that using a glass support structure at the back side of an IC structure with TFT memory may advantageously reduce parasitic effects of front end of line (FEOL) devices (e.g., FEOL transistors) in the IC structure, compared to using a silicon-based (Si) support structure at the back. Arranging a support structure with a dielectric constant lower than that of Si at the back of an IC structure may advantageously decrease various parasitic effects associated with the FEOL devices of the IC structure, since such parasitic effects are typically proportional to the dielectric constant of the surrounding medium.

A 3D semiconductor device including: a first level including a plurality of first single-crystal transistors; a plurality of memory control circuits formed from at least a portion of the plurality of first single-crystal transistors; a first metal layer disposed atop the plurality of first single-crystal transistors; a second metal layer disposed atop the first metal layer; a second level disposed atop the second metal layer, the second level including a plurality of second transistors; a third level including a plurality of third transistors, where the third level is disposed above the second level; a third metal layer disposed above the third level; and a fourth metal layer disposed above the third metal layer, where the plurality of second transistors are aligned to the plurality of first single crystal transistors with less than 140 nm alignment error, the second level includes first memory cells, the third level includes second memory cells.

A forming method of a semiconductor structure includes the following: providing a semiconductor substrate formed with a first mask layer having a preset pattern; forming a second mask layer having a first mask pattern on a surface of the first mask layer, wherein the first mask pattern includes a plurality of first sub-patterns arranged in sequence; forming a second mask pattern in the second mask layer through the first mask pattern in a self-alignment manner, wherein the second mask pattern includes the first sub-patterns of the first mask pattern and second sub-patterns corresponding to the first sub-patterns; etching the first mask layer based on the first sub-patterns and the second sub-patterns of the second mask pattern to convert the preset pattern into an active area pattern; and defining active areas in the semiconductor substrate based on the active area pattern.

A Fin FET semiconductor device includes a fin structure extending in a first direction and extending from an isolation insulating layer. The Fin FET device also includes a gate stack including a gate electrode layer, a gate dielectric layer, side wall insulating layers disposed at both sides of the gate electrode layer, and interlayer dielectric layers disposed at both sides of the side wall insulating layers. The gate stack is disposed over the isolation insulating layer, covers a portion of the fin structure, and extends in a second direction perpendicular to the first direction. A recess is formed in an upper surface of the isolation insulating layer not covered by the side wall insulating layers and the interlayer dielectric layers. At least part of the gate electrode layer and the gate dielectric layer fill the recess.

A semiconductor device and method of forming the same, the semiconductor device includes plural bit lines, plural conductive patterns, plural conductive pads and a spacer. The bit lines are disposed on a substrate, along a first direction. The conductive patterns are disposed on the substrate, along the first direction, wherein the conductive patterns and the bit lines are alternately arranged in a second direction perpendicular to the first direction. The conductive pads are arranged in an array and disposed over the conductive patterns and the bit lines. The spacer is disposed between the bit lines and the conductive patterns, under the conductive pads, wherein the spacers includes a tri-layered structure having a first layer, a second layer and a third layer, and the second layer includes a plurality of air gaps separated arranged along the first direction.

Some embodiments include an integrated assembly having digit lines extending along a first direction, and rails over the digit lines. The rails include semiconductor-material pillars alternating with intervening insulative regions. The rails have upper, middle and lower segments. A first insulative material is along the upper and lower segments of the rails. A second insulative material is along the middle segments of the rails. The second insulative material differs from the first insulative material in one or both of thickness and composition. Conductive gate material is along the middle segments of the rails and is spaced from the middle segments by the second insulative material. Channel regions are within the middle segments of the pillars, upper source/drain regions are within the upper segments of the pillars and lower source/drain regions are within the lower segments of the pillars. Some embodiments include methods of forming integrated assemblies.