A method for manufacturing a bonded wafer, includes: ion-implanting a gas ion such as a hydrogen ion from a surface of a bond wafer, thereby forming an ion-implanted layer; bonding the bond wafer and a base wafer; producing a bonded wafer having a thin-film on the base wafer by delaminating the bond wafer along the ion-implanted layer; and performing an RTA treatment on the bonded wafer in a hydrogen gas-containing atmosphere; wherein a protective film is formed onto the surface of the thin-film in a heat treatment furnace in the course of temperature-falling from the maximum temperature of the RTA treatment before the bonded wafer is taken out from the heat treatment furnace; and then the bonded wafer with the protective film being formed thereon is taken out from the heat treatment furnace, and is then cleaned with a cleaning liquid which can etch the protective film and the thin-film.

A method of etching a layer including at least one pattern that has flanks is provided, including at least one step of modifying the layer by putting the layer in presence with a plasma into which C.sub.xH.sub.y is introduced and which includes ions heavier than hydrogen; and wherein the plasma creates a bombardment of ions with a hydrogen base coming from the C.sub.xH.sub.y, the bombardment being anisotropic according to a main direction of implantation parallel to the flanks and so as to modify portions of the layer that are inclined with respect to the main direction and so as to retain unmodified portions on the flanks, wherein chemical species of the plasma form a carbon film on the flanks; and at least one step of removing the modified layer to be etched using a selective etching of modified portions of the layer with respect to the carbon film.

According to an embodiment of a method of forming a semiconductor device, a semiconductor layer including a first dopant species of a first conductivity type and a second dopant species of a second conductivity type different from the first conductivity type is formed. The semiconductor layer is part of a semiconductor body having opposite first and second surfaces. Trenches are formed in the semiconductor layer at the first surface. The trenches are filled with a filling material including at least a semiconductor material. A thermal oxide is formed at one or both of the first and second surfaces, the thermal oxide having a thickness of at least 200 nm. Thermal processing of the semiconductor body causes diffusion of the first and second dopants species into the filling material.

The present invention application provides a method for manufacturing a SOI substrate, and the method comprising: providing a first semiconductor substrate; growing a first insulating layer on a top surface of the first semiconductor substrate for forming a first wafer; implanting a deuterium and hydrogen co-doping layer at a certain pre-determined depth of the first wafer; providing a second substrate; growing a second insulating layer on a top surface of the second semiconductor substrate for forming a second wafer; bonding the first wafer with the second wafer; annealing the first wafer and second wafer; separating a part of the first wafer from the second wafer; and forming a deuterium and hydrogen co-doping semiconductor layer on the second wafer.

The present disclosure provides a transistor, a transistor forming method thereof, and a semiconductor device. The transistor forming method comprises providing a substrate, the substrate comprising a first region for forming a source region and a second region for forming a drain region; forming a gate groove in the substrate to separate the first region and the second region, a part of the substrate along the bottom of the gate groove being used for constituting an embedded channel region of a transistor; forming a gate dielectric layer on the gate groove of the substrate to cover the embedded channel region and to extend to cover a side of the first region and a side of the second region in the gate groove; and forming a gate conductive layer on the gate dielectric layer of the substrate and in the gate groove.

A method includes: doping a region through a first surface of a semiconductor substrate; forming a plurality of doped structures within the semiconductor substrate, wherein each of the plurality of doped structures extends along a vertical direction and is in contact with the doped region; forming a plurality of transistors over the first surface, wherein each of the transistors comprises one or more source/drain structures electrically coupled to the doped region through a corresponding one of the doped structures; forming a plurality of interconnect structures over the first surface, wherein each of the interconnect structures is electrically coupled to at least one of the transistors; and testing electrical connections between the interconnect structures and the transistors based on detecting signals present on the doped region through a second surface of the semiconductor substrate, the second surface opposite to the first surface.

This disclosure provides for robust isolation across the SOI structure. In contrast to forming a charge trap layer in specific areas on the structure, a charge trap layer may be built across the insulating/substrate interface. The charge trap layer may be an implantation layer formed throughout and below the insulation layer. Devices built on this SOI structure have reduced cross-talk between the devices. Due to the uniform structure, isolation is robust across the structure and not confined to certain areas. Additionally, deep trench implantation is not required to form the structure, eliminating cost. The semiconductor-on-insulator substrate may include an active silicon layer over an oxide layer. The oxide layer may be over a charge trap layer. The charge trap layer may be over a silicon substrate.

Producing a semiconductor or piezoelectric on-insulator type substrate for RF applications which is provided with a porous layer under the BOX layer and under a layer of polycrystalline semiconductor material.

A semiconductor device is provided that includes a semiconductor substrate having a first main surface and a second main surface facing each other; a dielectric layer laminated on the first main surface of the semiconductor substrate; a first electrode layer laminated on the dielectric layer; and a protective layer covering at least an outer peripheral end of the dielectric layer and an outer peripheral end of the first electrode layer. Moreover, the protective layer is provided to expose an outer peripheral end on the first main surface of the semiconductor substrate. The semiconductor substrate includes a high-resistance region positioned at least directly under an outer peripheral end of the protective layer.

This disclosure provides for robust isolation across the SOI structure. In contrast to forming a charge trap layer in specific areas on the structure, a charge trap layer may be built across the insulating/substrate interface. The charge trap layer may be an implantation layer formed throughout and below the insulation layer. Devices built on this SOI structure have reduced cross-talk between the devices. Due to the uniform structure, isolation is robust across the structure and not confined to certain areas. Additionally, deep trench implantation is not required to form the structure, eliminating cost. The semiconductor-on-insulator substrate may include an active silicon layer over an oxide layer. The oxide layer may be over a charge trap layer. The charge trap layer may be over a silicon substrate.