A method for forming a semiconductor device structure is provided. The method for forming a semiconductor device structure includes forming a fin structure over a substrate. The fin structure includes first semiconductor layers and second semiconductor layers alternately stacked. The method for forming the semiconductor device structure also includes removing the first semiconductor layers of the fin structure in a channel region thereby exposing the second semiconductor layers of the fin structure. The method for forming the semiconductor device structure also includes forming a dielectric material surrounding the second semiconductor layers, and treating a first portion of the dielectric material. The method for forming the semiconductor device structure also includes etching the first portion of the dielectric material to form gaps, and filling the gaps with a gate stack.

A method of fabricating an integrated circuit (IC) structure, includes forming a gate trench that exposes a portion of each of a plurality of fins and forming a threshold voltage (Vt) tuning dielectric layer in the gate trench over the plurality of fins. Properties of the Vt tuning dielectric layer are adjusted during the forming to achieve a different Vt for each of the plurality of fins. The method also includes forming a glue metal layer over the Vt tuning dielectric layer; and forming a fill metal layer over the glue metal layer. The fill metal layer has a substantially uniform thickness over top surfaces of the plurality of fins.

Embodiments described herein generally relate to methods of manufacturing an oxide/polysilicon (OP) stack of a 3D memory cell for memory devices, such as NAND devices. The methods generally include treatment of the oxide and/or polysilicon materials with precursors during PECVD processes to lower the dielectric constant of the oxide and reduce the resistivity of the polysilicon. In one embodiment, the oxide material is treated with octamethylcyclotetrasiloxane (OMCTS) precursor. In another embodiment, germane (GeH.sub.4) is introduced to a PECVD process to form Si.sub.xGe.sub.(1-x) films with dopant. In yet another embodiment, a plasma treatment process is used to nitridate the interface between layers of the OP stack. The precursors and plasma treatment may be used alone or in any combination to produce OP stacks with low dielectric constant oxide and low resistivity polysilicon.

A magnetic device for magnetic random access memory (MRAM), spin torque MRAM, or spin torque oscillator technology is disclosed wherein a magnetic tunnel junction (MTJ) with a sidewall is formed between a bottom electrode and a top electrode. A passivation layer that is a single layer or multilayer comprising one of B, C, or Ge, or an alloy thereof wherein the B, C, and Ge content, respectively, is at least 10 atomic % is formed on the MTJ sidewall to protect the MTJ from reactive species during subsequent processing including deposition of a dielectric layer that electrically isolates the MTJ from adjacent MTJs, and during annealing steps around 400 C. in CMOS fabrication. The single layer is about 3 to 10 Angstroms thick and may be an oxide or nitride of B, C, or Ge. The passivation layer is preferably amorphous to prevent diffusion of reactive oxygen or nitrogen species.

A fabricating method of a stop layer includes providing a substrate. The substrate is divided into a memory region and a peripheral circuit region. Two conductive lines are disposed within the peripheral circuit region. Then, an atomic layer deposition is performed to form a silicon nitride layer to cover the conductive lines. Later, after forming the silicon nitride layer, a silicon carbon nitride layer is formed to cover the silicon nitride layer. The silicon carbon nitride layer serves as a stop layer.

A nitrogen plasma treatment is used on an adhesion layer of a contact plug. As a result of the nitrogen plasma treatment, nitrogen is incorporated into the adhesion layer. When a contact plug is deposited in the opening, an interlayer of a metal nitride is formed between the contact plug and the adhesion layer. A nitrogen plasma treatment is used on an opening in an insulating layer. As a result of the nitrogen plasma treatment, nitrogen is incorporated into the insulating layer at the opening. When a contact plug is deposited in the opening, an interlayer of a metal nitride is formed between the contact plug and the insulating layer.

The present disclosure relates to a semiconductor device and a manufacturing method, and more particularly to a semiconductor device having an enhanced gap fill layer in trenches. The present disclosure provides a novel gap fill layer formed using a multi-step deposition and in-situ treatment process. The deposition process can be a flowable chemical vapor deposition (FCVD) utilizing one or more assist gases and molecules of low reactive sticking coefficient (RSC). The treatment process can be an in-situ process after the deposition process and includes exposing the deposited gap fill layer to plasma activated assist gas. The assist gas can be formed of ammonia. The low RSC molecule can be formed of trisilylamin (TSA) or perhydropolysilazane (PHPS).

A semiconductor structure includes a channel structure, a gate structure, two source/drain features, and a plurality of inner spacers. The channel structure includes a plurality of channel features which are spaced apart from each other. The gate structure is disposed to surround the channel features. The source/drain features are disposed at two opposite sides of the channel structure such that each of the channel features interconnects the source/drain features. Each of the inner spacers is disposed to separate the gate structure from a corresponding one of the source/drain features. Each of the inner spacers includes an inner spacer body and a lateral nitrided portion. The lateral nitrided portion is in direct contact with the corresponding one of the source/drain features and has a nitrogen content greater than that of the inner spacer body.

A fabricating method of a stop layer includes providing a substrate. The substrate is divided into a memory region and a peripheral circuit region. Two conductive lines are disposed within the peripheral circuit region. Then, an atomic layer deposition is performed to form a silicon nitride layer to cover the conductive lines. Later, after forming the silicon nitride layer, a silicon carbon nitride layer is formed to cover the silicon nitride layer. The silicon carbon nitride layer serves as a stop layer.

A magnetic device for magnetic random access memory (MRAM), spin torque MRAM, or spin torque oscillator technology is disclosed wherein a magnetic tunnel junction (MTJ) with a sidewall is formed between a bottom electrode and a top electrode. A passivation layer that is a single layer or multilayer comprising one of B, C, or Ge, or an alloy thereof wherein the B, C, and Ge content, respectively, is at least 10 atomic % is formed on the MTJ sidewall to protect the MTJ from reactive species during subsequent processing including deposition of a dielectric layer that electrically isolates the MTJ from adjacent MTJs, and during annealing steps around 400 C. in CMOS fabrication. The single layer is about 3 to 10 Angstroms thick and may be an oxide or nitride of B, C, or Ge. The passivation layer is preferably amorphous to prevent diffusion of reactive oxygen or nitrogen species.