A method for forming the gate structure of the NAND memory, comprising the steps of disposing a gate structure layer, a pattern transfer layer, a TEOS structure, and an organic dielectric Tri-Layer on a substrate sequentially; performing a patterning using a first photomask and a first photoresist layer; performing an etching process to form a control gate structure, a peripheral gate structure and a select gate structure; performing a trimming process to them; patterning sidewalls on sides of them; performing a second patterning using a second photomask as a mask and a second photoresist layer to protect the peripheral gate structure, the select gate structure, and their sidewalls; removing the control gate structure between its sidewalls; performing etching by using the sidewalls, the peripheral gate structure and the select gate structure as masks to form the control gate, the peripheral gate, and the select gate.

A memory device includes a cell wafer including a memory cell array; a first logic wafer bonded to one surface of the cell wafer, and including a first logic circuit which controls the memory cell array; and a second logic wafer bonded to the other surface of the cell wafer which faces away from the one surface, and including a second logic circuit which controls the memory cell array.

A three-dimensional memory device includes an electrode structure including a plurality of interlayer dielectric layers and a plurality of electrode layers which are alternately stacked on a first substrate, each of the plurality of electrode layers having a pad part which does not overlap with another electrode layer positioned on the electrode layer; a pass transistor positioned below the first substrate; and a first contact passing through the electrode structure from the pad part of one of the plurality of electrode layers, and coupling the pad part and the pass transistor.

A memory opening or a line trench is formed through an alternating stack of insulating layers and sacrificial material layers. A memory opening fill structure or a memory stack assembly is formed, which includes a vertical stack of discrete intermediate metallic electrodes formed on sidewalls of the sacrificial material layers, a gate dielectric layer, and a vertical semiconductor channel. Backside recesses are formed by removing the sacrificial material layers selective to the insulating layers, and a combination of a ferroelectric dielectric layer and an electrically conductive layer within each of the backside recesses. The electrically conductive layer is laterally spaced from a respective one of the discrete intermediate metallic electrodes by the ferroelectric dielectric layer. Ferroelectric-metal-insulator memory elements are formed around the vertical semiconductor channel.

A flash memory is provided and includes a substrate including a memory cell region; a memory transistor array including memory transistors and selecting transistors in the memory cell region; a functional layer covering outer surfaces of the memory transistors and selecting transistors, as well as surfaces of the substrate between adjacent memory transistors and selecting transistors; a dielectric layer covering top surfaces of the memory transistors and selecting transistors and fills gaps between each selecting transistor and a corresponding adjacent memory transistor; and air gaps formed between adjacent memory transistors. Each selecting transistor is used for selecting one column of memory transistors in the memory transistor array. The functional layer has a roughened surface capable of absorbing water. The air gaps in the flash memory are water vapor induced air gaps.

The present disclosure provides a stack capacitor, a flash memory device, and a manufacturing method thereof. The stack capacitor of the flash memory device has a a memory transistor structure which at least comprises a substrate, and a tunneling oxide layer, a floating gate layer, an interlayer dielectric layer and a control gate layer which are sequentially stacked on the substrate, the interlayer dielectric layer of the stack capacitor comprises a first oxide layer and a nitride layer; the stack capacitor further comprises a first contact leading out of the control gate layer and a second contact leading out of the floating gate layer. The capacitance per unit area of the stack capacitor provided by the disclosure is effectively improved, and the size of the transistor device is reduced. The manufacturing method according to the disclosure does not add any additional photomask than a conventional process flow.

A method of forming a three-dimensional memory device includes forming a first-tier alternating stack of first insulating layers and first sacrificial material layers, forming first-tier memory openings, first-tier support openings, and first-tier moat trenches through the first alternating stack using a same etching step, forming a first dielectric moat structure in the first moat tier-trenches and first support pillar structures in the first-tier support openings during a same deposition step, forming memory stack structures in the first-tier memory openings, forming backside trenches through the first-tier alternating stack after forming the first dielectric moat structure, replacing portions of the first sacrificial material layers with first electrically conductive layers through the backside trenches, and forming at least one through-memory-level interconnection via structure through the first vertically alternating sequence of first insulating plates and first dielectric material plates surrounded by the first dielectric moat structure.

A semiconductor device includes a first stack structure on a substrate, and a second stack structure on the first stack structure. A channel structure extends through the first stack structure and the second stack structure. A first auxiliary stack structure including a plurality of first insulating layers and a plurality of first mold layers are alternately stacked on the substrate. An alignment key extends into the first auxiliary stack structure and protrudes to a higher level than an uppermost end of the first stack structure. A second auxiliary stack structure is disposed on the first auxiliary stack structure and the alignment key, and includes a plurality of second insulating layers and a plurality of second mold layers alternately stacked. The second auxiliary stack structure includes a protrusion aligned with the alignment key.

Embodiments of three-dimensional (3D) memory devices and fabricating methods thereof are disclosed. The method includes: forming an alternating dielectric stack on a substrate; forming a structure strengthen plug in an upper portion of the alternating dielectric stack, wherein the structure strengthen plug has a narrow support body and two enlarged connecting portions; forming a gate line silt in the alternating dielectric stack to expose a sidewall of one enlarged connecting portion of the structure strengthen plug; and forming a gate line slit structure in the gate line slit including an enlarged end portion connected to the one enlarged connecting portion of the structure strengthen plug.

A three-dimensional memory device includes a lower stack and an upper stack stacked one on the other, and each including a plurality of word lines which are stacked alternately with a plurality of interlayer dielectric layers, wherein each of the lower stack and the upper stack includes a first cell part, a second cell part, a coupling part which couples the first cell part and the second cell part, and a staircase part which extends parallel to the coupling part from the first cell part and in which pad areas of the word lines are disposed in a stepwise manner, and wherein the coupling part of the upper stack is disposed to overlap with the staircase part of the lower stack, and the staircase part of the upper stack is disposed to overlap with the coupling part of the lower stack.