There is provided a technique that includes: a first nozzle arranged to correspond to a first region where a plurality of product substrates are arranged in a substrate arrangement region where a plurality of substrates are arranged in a reaction tube, the first nozzle supplying a hydrogen-containing gas into the reaction tube; a second nozzle arranged to correspond to the first region and supplying an oxygen-containing gas into the reaction tube; a third nozzle arranged closer to the bottom opening than the first region to correspond to a second region where a dummy substrate or a heat insulator or both is arranged, the third nozzle supplying a dilution gas into the reaction tube; and a controller configured to be capable of controlling the hydrogen-containing gas and the dilution gas so that a concentration of the hydrogen-containing gas in the second region is lower than that in the first region.

A semiconductor structure is provided. The semiconductor structure includes a base substrate including a plurality of non-device regions; a middle fin structure and an edge fin disposed around the middle fin structure on the base substrate between adjacent non-device regions; a first barrier layer on sidewalls of the edge fin; and an isolation layer on the base substrate. The isolation layer has a top surface lower than the edge fin and the middle fin structure, and covers a portion of the sidewalls of each of the edge fin and the middle fin structure. The isolation layer further has a material density smaller than the first barrier layer.

A thin film transistor includes an active layer including a first portion having a first thickness and a second portion having a second thickness greater than the first thickness, a capping layer filling a thickness difference between the first portion and the second portion and arranged on the first portion, a gate insulating layer arranged on the capping layer, a gate electrode on the active layer, wherein the gate insulating layer and the capping layer are disposed between the gate electrode and the active layer, and a source electrode and a drain electrode connected to the active layer.

A semiconductor storage device includes first and second stacked bodies, a first semiconductor layer, a first charge storage layer, a conductive layer, and a first silicon oxide layer. The first stacked body includes first insulation layers and first gate electrode layers that are alternately stacked in a first direction. The first semiconductor layer extends in the first stacked body in the first direction. The first charge storage layer is provided between the first semiconductor layer and the first gate electrode layers. The conductive layer is provided between the first stacked body and the second stacked body and extends in the first direction and a second direction. The first silicon oxide layer is provided between the conductive layer and the first gate electrode layers. The first silicon oxide layer containing an impurity being at least one of phosphorus, boron, carbon, and fluorine.

Methods of doping a semiconductor material are disclosed. Some embodiments provide for conformal doping of three dimensional structures. Some embodiments provide for doping with high concentrations of boron for p-type doping.

A semiconductor device includes a core insulating layer extending in a first direction, an etch stop layer disposed on the core insulating layer, a channel layer extending along a sidewall of the core insulating layer and a sidewall of the etch stop layer, conductive patterns each surrounding the channel layer and stacked to be spaced apart from each other in the first direction, and an impurity region formed in an upper end of the channel layer.

A semiconductor device including an oxide-nitride-oxide (ONO) structure having a multi-layer charge storing layer and methods of forming the same are provided. Generally, the method involves: (i) forming a first oxide layer of the ONO structure; (ii) forming a multi-layer charge storing layer comprising nitride on a surface of the first oxide layer; and (iii) forming a second oxide layer of the ONO structure on a surface of the multi-layer charge storing layer. Preferably, the charge storing layer comprises at least two silicon oxynitride layers having differing stoichiometric compositions of Oxygen, Nitrogen and/or Silicon. More preferably, the ONO structure is part of a silicon-oxide-nitride-oxide-silicon (SONOS) structure and the semiconductor device is a SONOS memory transistor. Other embodiments are also disclosed.

The present disclosure provides a 1T1R resistive random access memory and a manufacturing method thereof, and a device. The 1T1R resistive random access memory includes: a memory cell array composed of multiple 1T1R resistive random access memory cells, each 1T1R resistive random access memory cell including a transistor and a resistance switching device (30). The transistor includes a channel layer (201), a gate layer (204) insulated from the channel layer (201), and a drain layer (203) and a source layer (202) disposed on the channel layer (201), and the drain layer (203) and the source layer (202) are vertically distributed on the channel layer (201). The resistance change device (30) is disposed near the drain layer (203). The disclosure reduces the area of a transistor, thereby significantly improving the memory density of the resistive random access memory.

Various embodiments of the present application are directed towards a semiconductor-on-insulator (SOI) substrate. The SOI substrate includes a handle substrate; a device layer overlying the handle substrate; and an insulator layer separating the handle substrate from the device layer. The insulator layer meets the device layer at a first interface and meets the handle substrate at a second interface. The insulator layer comprises a getter material having a getter concentration profile. The handle substrate contains getter material and has a handle getter concentration profile. The handle getter concentration profile has a peak at the second interface and a gradual decline beneath the second interface until reaching a handle getter concentration.

A rotation driving mechanism includes a turntable configured to rotate about a first axis, and a rotating plate disposed along a circumferential direction of the turntable and configured to rotate about a second axis independently of a rotation of the turntable. A driving plate is coaxially disposed with the first axis and is rotatable differently in rotational direction and rotational speed from the rotation of the turntable. A trajectory plate is fixed to the driving plate and disposed in the vicinity of the second axis of the rotating plate. The trajectory plate includes a rolling trajectory groove in a surface. The trajectory groove has a curved shape in a plan view. A horizontal rotating member is coupled to and fixed to the rotating plate and engaged with the rolling trajectory groove. The horizontal rotating member rotates the rotating plate by moving and rolling through the rolling trajectory groove.