A method for manufacturing an oxide layer includes: reacting a nitrogen-oxide-containing gas with hydrogen at a first temperature to form a first oxide layer, a volume concentration of the hydrogen in a first reaction gas being a first concentration; and reacting oxygen with hydrogen at a second temperature to form a second oxide layer on a surface of the first oxide layer, a volume concentration of the hydrogen in a second reaction gas being a second concentration; where the first temperature is less than the second temperature, and the first concentration is greater than the second concentration.

An example memory device includes a channel positioned between and electrically connecting a first diffusion region and a second diffusion region, and a tunnel dielectric layer, a multi-layer charge trapping layer, and a blocking dielectric layer disposed between the gate structure and the channel. The multi-layer charge trapping layer includes a first dielectric layer disposed abutting a second dielectric layer and an anti-tunneling layer disposed between the first and second dielectric layers. The anti-tunneling layer includes an oxide layer. The first dielectric layer includes oxygen-rich nitride and the second dielectric layer includes oxygen-lean nitride.

A method of forming a semiconductor device includes receiving a device having a substrate and a first dielectric layer surrounding a gate trench. The method further includes depositing a gate dielectric layer and a gate work function (WF) layer in the gate trench, and forming a hard mask (HM) layer in a space surrounded by the gate WF layer. The method further includes recessing the gate WF layer such that a top surface of the gate WF layer in the gate trench is below a top surface of the first dielectric layer. After the recessing of the gate WF layer, the method further includes removing the HM layer in the gate trench. After the removing of the HM layer, the method further includes depositing a metal layer in the gate trench.

One aspect of the disclosure relates to a method of forming an integrated circuit structure. The method may include: forming a first work function metal over a set of fins having at least a first fin and a second fin; implanting the first work function metal with a first species; removing the implanted first work function metal from over the first fin such that a remaining portion of the implanted first work function metal remains over the second fin; forming a second work function metal over the set of fins including over the remaining portion of the implanted first work function metal; implanting the second work function metal with a second species; and forming a metal over the implanted second work function metal over the set of fins thereby forming the gate stack.

According to an embodiment, a semiconductor memory device comprises: control gate electrodes stacked above a substrate; a semiconductor layer that extends in a first direction above the substrate and faces the control gate electrodes; and a gate insulating layer provided between these control gate electrode and semiconductor layer. The gate insulating layer comprises: a first insulating layer covering a side surface of the semiconductor layer; a charge accumulation layer covering a side surface of this first insulating layer; and a second insulating layer including a metal oxide and covering a side surface of this charge accumulation layer. The charge accumulation layer has: a first portion facing the control gate electrode; and a second portion facing a region between control gate electrodes adjacent in the first direction and including more oxygen than the first portion.

Various methods include providing a substrate, forming a projection extending upwardly from the substrate, the projection having a channel region therein, and forming a gate structure engaging the projection adjacent to the channel region, the gate structure having spaced first and second conductive layers and a strain-inducing conductive layer disposed between the first and second conductive layers. The method also includes forming epitaxial growths on portions of the projection at each side of the gate structure, the epitaxial growths imparting a first strain to the channel region, and imparting a second strain to the channel region, including performing at least one stress memorization technique on the gate structure such that the strain-inducing conductive layer imparts the second strain to the channel region, and removing the capping layer, wherein the imparting the second strain is carried out in a manner that imparts tensile strain to the channel region.

A semiconductor device includes a stacked structure having channel formation region layers CH.sub.1 and CH.sub.2, gate electrode layers G.sub.1, G.sub.2, and G.sub.3 alternately arranged on a base, in which a lowermost layer of the stacked structure is formed with a 1.sup.st layer G.sub.1 of the gate electrode layers, an uppermost layer of the stacked structure is formed with an N.sup.th (where N≥3) layer G.sub.3 of the gate electrode layers, the gate electrode layers each have a first end face, a second end face, a third end face opposing the first end face, and a fourth end face opposing the second end face, the first end face of odd-numbered layers G.sub.1, G.sub.3 of the gate electrode layers is connected to a first contact portion, and the third end face of an even-numbered layer G.sub.2 of the gate electrode layers is connected to a second contact portion.

A method for fabricating semiconductor device is disclosed. The method includes the steps of: providing a substrate; forming an interfacial layer on the substrate; forming a stack structure on the interfacial layer; patterning the stack structure to form a gate structure on the interfacial layer; forming a liner on the interfacial layer and the gate structure; and removing part of the liner and part of the interfacial layer for forming a spacer.

In order to improve the characteristics of a semiconductor device including: a channel layer and a barrier layer formed above a substrate; and a gate electrode arranged over the barrier layer via a gate insulating film, the semiconductor device is configured as follows. A silicon nitride film is provided over the barrier layer between a source electrode and the gate electrode, and is also provided over the barrier layer between a drain electrode and the gate electrode GE. The surface potential of the barrier layer is reduced by the silicon nitride film, thereby allowing two-dimensional electron gas to be formed. Thus, by selectively forming two-dimensional electron gas only in a region where the silicon nitride film is formed, a normally-off operation can be performed even if a trench gate structure is not adopted.

Present embodiments provide for a FinFET and fabrication method thereof. The fabrication method includes two selective etching processes to form the channel. The FinFET includes a substrate, a shallow trench isolation (STI) layer, a buffer layer, a III-V group material, an oxide-isolation layer, a high-K dielectric layer and a conductor material. The STI is formed on the substrate with a trench. The buffer layer is formed on the substrate in the trench. The III-V group material is formed on the buffer layer in vertical stacked bowl shape. The oxide-isolation layer is formed between the substrate and the III-V group material. The high-K dielectric layer is formed on the STI layer and surrounding the III-V group material. The conductor material is formed surrounding the high-K dielectric layer.