A semiconductor substrate includes excavations which form trenches sunk. A capacitive element includes: a first dielectric envelope conforming to sides and bottoms of the trenches; a first semiconductor layer conforming to a surface of the first dielectric envelope in the trenches; a second dielectric envelope conforming to a surface of the first semiconductor layer in the trenches; and a second semiconductor layer conforming to a surface of the second dielectric envelope in the trenches.

A method of forming a semiconductor device includes implanting dopants of a first conductivity type into a semiconductor substrate to form a first well, epitaxially growing a channel layer over the semiconductor substrate, forming a fin from the second semiconductor material, and forming a gate structure over a channel region of the fin. The semiconductor substrate includes a first semiconductor material. Implanting the dopants may be performed at a temperature in a range of 150° C. to 500° C. The channel layer may include a second semiconductor material. The channel layer may be doped with dopants of the first conductivity type.

A method for fabricating an integrated circuit is disclosed. The method comprises forming a semiconductor ridge over a semiconductor surface of a substrate and forming an implant screen on a top and sidewalls of the semiconductor ridge. The implant screen is at least two times thicker on the top of the semiconductor ridge relative to the sidewalls of the semiconductor ridge. The method further comprises implanting a dopant into the top and sidewalls of the semiconductor ridge.

A method for forming a semiconductor structure. Two isolation structures are formed in a semiconductor. A cavity is etched in the semiconductor between the two isolation structures in the semiconductor. Dopants are implanted into a bottom side of the cavity to form a doped region in the semiconductor below the cavity between the two isolation structures. A contact is formed in the cavity. The contact is on the doped region and in direct contact with the doped region.

Methods and structures formed thereby are described relating to the doping non-planar fin structures. An embodiment of a structure includes a substrate, wherein the substrate comprises silicon, a fin on the substrate comprising a first portion and a second portion; and a dopant species, wherein the first portion comprises a first dopant species concentration, and the second portion comprises a second dopant species concentration, wherein the first dopant species concentration is substantially less than the second dopant species concentration.

A semiconductor substrate includes excavations which form trenches sunk. A capacitive element includes: a first dielectric envelope conforming to sides and bottoms of the trenches; a first semiconductor layer conforming to a surface of the first dielectric envelope in the trenches; a second dielectric envelope conforming to a surface of the first semiconductor layer in the trenches; and a second semiconductor layer conforming to a surface of the second dielectric envelope in the trenches.

A semiconductor substrate includes excavations which form trenches sunk. A capacitive element includes: a first dielectric envelope conforming to sides and bottoms of the trenches; a first semiconductor layer conforming to a surface of the first dielectric envelope in the trenches; a second dielectric envelope conforming to a surface of the first semiconductor layer in the trenches; and a second semiconductor layer conforming to a surface of the second dielectric envelope in the trenches.

A method for manufacturing a semiconductor device having a junction field effect transistor, includes: preparing a substrate having a first conductivity type drift layer; forming a first conductivity type channel layer above the drift layer by an epitaxial growth, to thereby produce a semiconductor substrate; forming a second conductivity type gate layer within the channel layer by performing an ion-implantation; forming a second conductivity type body layer at a position separated from the gate layer within the channel layer by performing an ion-implantation; and forming a second conductivity type shield layer at a position that is to be located between the gate layer and the drift layer within the channel layer by performing an ion-implantation. The shield layer is formed to face the gate layer while being separated from the gate layer, and is kept to a potential different from that of the gate layer.

The present disclosure is directed to a vertical-channel semiconductor device. For manufacturing the vertical-channel semiconductor device, starting from a work wafer having a first side and a second side opposite to the first side along a direction, a first doped region is formed in the work wafer, from the second side of the work wafer. The work wafer has a first conductivity type and a first doping level, the first doped region has the first conductivity type and a second doping level higher than the first doping level. A device active region having a channel region extending in the direction is formed in the work wafer, on the first side of the work wafer. The first doped region and the device active region delimit, in the work wafer, a drift region. The first doped region is formed before the device active region.

A method of manufacturing a semiconductor integrated circuit, includes: forming a first well region having a second conductivity type in an upper portion of a support layer having a first conductivity type; forming an oxide film on the first well region by a thermal oxidation method to decrease a concentration of impurities at an top surface of top surface side of the first well region; removing the oxide film; forming a second well region having the first conductivity type in an upper portion of the first well region; and merging a semiconductor element having a main electrode region having the second conductivity type in the second well region.