A method of making a silicon carbide MOSFET device can include: providing a substrate with a first doping type; forming a patterned first barrier layer on a first surface of the substrate; forming a source region with a first doping type in the substrate; forming a base region with a second doping type and a contact region with a second doping type in the substrate, and forming a gate structure. The first barrier layer can include a first portion and a second portion, the first portion can include a semiconductor layer and a removable layer different from the semiconductor layer, and the second portion can only include the removable layer.

According to an embodiment, a nonvolatile semiconductor memory device comprises a plurality of conductive layers stacked in a first direction via an inter-layer insulating layer. In addition, the nonvolatile semiconductor memory device comprises: a semiconductor layer having the first direction as a longer direction; a tunnel insulating layer contacting a side surface of the semiconductor layer; a charge accumulation layer contacting a side surface of the tunnel insulating layer; and a block insulating layer contacting a portion facing the conductive layer, of a side surface of the charge accumulation layer. Moreover, the portion facing the conductive layer, of the charge accumulation layer is thinner compared to a portion facing the inter-layer insulating layer, of the charge accumulation layer.

A substrate oxidation assembly includes: a chamber body defining a processing volume; a substrate support disposed in the processing volume; a plasma source coupled to the processing volume; a steam source fluidly coupled to the processing volume; and a substrate heater. A method of processing a semiconductor substrate includes: initiating conformal radical oxidation of high aspect ratio structures of the substrate comprising: heating the substrate; and exposing the substrate to steam; and conformally oxidizing the substrate. A semiconductor device includes a silicon and nitrogen containing layer; a feature formed in the silicon and nitrogen containing layer having an aspect ratio of at least 40:1; and an oxide layer on the face of the feature having a thickness in a bottom region of the silicon and nitrogen containing layer that is at least 95% of a thickness of the oxide layer in a top region.

An electrostatic discharge protection structure includes: substrate of a first type of conductivity, well region of a second type of conductivity, substrate contact region in the substrate and of the first type of conductivity, well contact region in the well region and of the second type of conductivity, substrate counter-doped region between the substrate contact region and the well contact region and of the second type of conductivity, well counter-doped region between the substrate contact region and the well contact region and of the first type of conductivity, communication region at a lateral junction between the substrate and the well region, first isolation region between the substrate counter-doped region and the communication region, second isolation region between the well counter-doped region and the communication region, oxide layer having one end on the first isolation region and another end on the substrate, and field plate structure on the oxide layer.

The present disclosure discloses a method for preparing an isolation area of a gallium oxide device, the method comprising: depositing a mask layer on a gallium oxide material; removing a preset portion region of the mask layer; preparing an isolation area in a position, corresponding to the preset portion region, on the gallium oxide material by using a high-temperature oxidation technique, with the isolation area being located between active areas of the gallium oxide device; and removing the remaining mask layer on the gallium oxide material. In the disclosure, the isolation area is prepared by using the high-temperature oxidation technique, which prevents damage to the gallium oxide device during the preparation of the isolation area, thereby achieving isolation between the active areas of the gallium oxide device.

Discrete silicon nitride portions can be formed at each level of electrically conductive layers in an alternating stack of insulating layers and the electrically conductive layers. The discrete silicon nitride portions can be employed as charge trapping material portions, each of which is laterally contacted by a tunneling dielectric portion on the front side, and by a blocking dielectric portion on the back side. The tunneling dielectric portions may be formed as discrete material portions or portions within a tunneling dielectric layer. The blocking dielectric portions may be formed as discrete material portions or portions within a blocking dielectric layer. The discrete silicon nitride portions can be formed by depositing a charge trapping material layer and selectively removing portions of the charge trapping material layer at levels of the insulating layers. Various schemes may be employed to singulate the charge trapping material layer.

Examples of an integrated circuit with a strain-generating liner and a method for forming the integrated circuit are provided herein. In some examples, an integrated circuit device includes a substrate, a fin extending from the substrate, and a gate disposed on the fin. The gate has a bottom portion disposed towards the fin and a top portion disposed on the bottom portion. A liner is disposed on a side surface of the bottom portion of the gate such that the top portion of the gate is free of the liner. In some such examples, the liner is configured to produce a channel strain.

This invention relates to a method for bonding of a first contact surface of a first substrate to a second contact surface of a second substrate with the following steps, especially the following sequence: forming a first reservoir in a surface layer on the first contact surface and a second reservoir in a surface layer on the second contact surface, the surface layers of the first and second contact surfaces being comprised of respective native oxide materials of one or more second educts respectively contained in reaction layers of the first and second substrates, partially filling the first and second reservoirs with one or more first educts; and reacting the first educts filled in the first reservoir with the second educts contained in the reaction layer of the second substrate to at least partially strengthen a permanent bond formed between the first and second contact surfaces.

Provided is a memory device including a substrate, a plurality of word-line structures, a plurality of cap structures, and a plurality of air gaps. The word-line structures are disposed on the substrate. The cap structures are respectively disposed on the word-line structures. A material of the cap structures includes a nitride. The nitride has a nitrogen concentration decreasing along a direction near to a corresponding word-line structure toward far away from the corresponding word-line structure. The air gaps are respectively disposed between the word-line structures. The air gaps are in direct contact with the word-line structures. A method of forming a memory device is also provided.

A semiconductor device includes a spacer having a nitride/oxide/nitride (NON) structure. The spacer is disposed between a sidewall of a bit line and a bit line contact and a sidewall of a storage node contact plug to reduce coupling capacitance between the bit line and a storage node contact plug and between the bit line contact and the storage node contact plug.