A finned structure is fabricated using a bulk silicon substrate having a carbon-doped epitaxial silicon germanium layer. A pFET region of the structure includes fins having silicon germanium top portions and an epitaxial carbon-doped silicon germanium diffusion barrier that suppresses dopant diffusion from the underlying n-well into the silicon germanium fin region during device fabrication. The structure further includes an nFET region including silicon fins formed from the substrate. The carbon-doped silicon germanium diffusion barrier has the same or higher germanium content than the silicon germanium fins.

A semiconductor device includes a semiconductor substrate having a first region and a second region, a plurality of first semiconductor fins in the first region, a plurality of second semiconductor fins in the second region, a first solid-state dopant source layer within the first region on the semiconductor substrate, a first insulating buffer layer on the first solid-state dopant source layer, a second solid-state dopant source layer within the second region on the semiconductor substrate, a second insulating buffer layer on the second solid-state dopant source layer and on the first insulating buffer layer, a first fin bump in the first region, and a second fin bump in the second region. The first fin bump includes a first sidewall spacer and the second fin bump comprises a second sidewall spacer. The first sidewall spacer has a structure that is different from that of the second sidewall spacer.

Embodiments of the present disclosure relate to the field of semiconductors, and provide a semiconductor structure and a fabrication method thereof, and a memory. The semiconductor structure includes: a base substrate including a first side and a second side opposite to each other; a first device layer including a first device, the first device layer being arranged on the first side of the base substrate; and a second device layer including a second device, the second device layer being arranged on the second side of the base substrate. At least part of the first device and at least part of the second device share a first doped region.

A method for controlling voltage of a doped well in a substrate is provided. The substrate and the doped well are in different conductive type. The method includes applying a substrate voltage to the substrate while a well power for applying a well voltage to the doped well is turned off. The method also includes detecting a voltage level of one of the doped well and the substrate to judge whether or not a voltage target is reached. The well power is turned on to apply the well voltage to the doped well when the voltage level as detected reaches to the voltage target.

A semiconductor device includes first and second voltage device regions and a deep well common to the first and second voltage device regions. An operation voltage of electronic devices in the second voltage device region is higher than that of electronic devices in the first voltage device region. The deep well has a first conductivity type. The first voltage device region includes a first well having the second conductivity type and a second well having the first conductivity type. The second voltage region includes a third well having a second conductivity type and a fourth well having the first conductivity type. A second deep well having the second conductivity type is formed below the fourth well. The first, second and third wells are in contact with the first deep well, and the fourth well is separated by the second deep well from the first deep well.

A monolithically integrated MOS transistor, comprising a doped well region of a first conductivity type, an active MOS transistor region formed in the well region, comprising doped source and drain regions of a second conductivity type and at least one MOS channel region extending between the source and drain regions under a respective gate stack, and a dielectric isolation layer of the STI or LOCOS type and laterally surrounding same, wherein well portions of the well region adjoin the MOS channel region in the two opposite longitudinal directions oriented perpendicular to a notional connecting line extending from the source through the MOS channel region to the drain region, and which extend as far as a surface of the active MOS transistor region, so that the respective well portion adjoining the MOS channel region is arranged between the MOS channel region and the dielectric isolation layer.

A semiconductor device is provided comprising a silicon-on-insulator (SOI) substrate comprising a semiconductor bulk substrate, a buried oxide layer formed on the semiconductor bulk substrate and a semiconductor layer formed on the buried oxide layer and a transistor device, wherein the transistor device comprises a gate electrode formed by a part of the semiconductor bulk substrate, a gate insulation layer formed by a part of the buried oxide layer and a channel region formed in a part of the semiconductor layer.

A method includes forming an N well and a P well in a substrate; depositing a first layer having silicon over the N well and the P well; depositing a first dielectric layer over the first layer; forming a resist pattern over the first dielectric layer, the resist pattern providing an opening directly above the N well; etching the first dielectric layer and the first layer through the opening, leaving a first portion of the first layer over the N well; removing the resist pattern; and epitaxially growing a second layer having silicon germanium (SiGe) over the first portion of the first layer. The epitaxially growing the second layer includes steps of (a) performing a baking process, (b) depositing a silicon seed layer, and (c) depositing a SiGe layer over the silicon seed layer, wherein the steps (a), (b), and (c) are performed under about a same temperature.

A semiconductor device can include: a substrate having a first doping type; a first well region located in the substrate and having a second doping type, where the first well region is located at opposite sides of a first region of the substrate; a source region and a drain region located in the first region, where the source region has the second doping type, and the drain region has the second doping type; and a buried layer having the second doping type located in the substrate and below the first region, where the buried layer is incontact with the first well region, where the first region is surrounded by the buried layer and the first well region, and the first doping type is opposite to the second doping type.

An integration manufacturing method of a high voltage device and a low voltage device includes: providing a substrate; forming a semiconductor layer on the substrate; forming insulation regions on the semiconductor layer, for defining a high voltage device region and a low voltage device region; forming a first high voltage well in the high voltage device region; forming a second high voltage well in the semiconductor layer, wherein the first high voltage well and the second high voltage well are in contact with each other in a channel direction; forming an oxide layer on the semiconductor layer, wherein the oxide layer overlays the high voltage device region and the low voltage device region; and forming a first low voltage well in the low voltage device region in the semiconductor layer.