A channel stop and well dopant migration control implant (e.g., of argon) can be used in the fabrication of a transistor (e.g., PMOS), either around the time of threshold voltage adjust and well implants prior to gate formation, or as a through-gate implant around the time of source/drain extension implants. With its implant depth targeted about at or less than the peak of the concentration of the dopant used for well and channel stop implants (e.g., phosphorus) and away from the substrate surface, the migration control implant suppresses the diffusion of the well and channel stop dopant to the surface region, a more retrograde concentration profile is achieved, and inter-transistor threshold voltage mismatch is improved without other side effects. A compensating through-gate threshold voltage adjust implant (e.g., of arsenic) or a threshold voltage adjust implant of increased dose can increase the magnitude of the threshold voltage to a desired level.

Horizontal gate-all-around devices and methods of manufacturing same are described. The hGAA devices comprise a doped semiconductor material between source regions and drain regions of the device. The method includes doping semiconductor material layers between source regions and drain regions of an electronic device.

A transistor structure can include a semiconductor-on-insulator substrate that includes an upper substrate region separated from a lower substrate region by a buried insulator. Shallow halo implant regions can be formed in an upper substrate region having a peak concentration at a first depth within the upper substrate region. Deep halo implant regions can be formed in the upper substrate region having a peak concentration at a second depth lower than the first depth. An epitaxial layer can be formed on top of the upper substrate region and below the control gate. Source and drain regions both of a second conductivity type formed in at least the epitaxial layer. In some embodiments, a lower substrate region can be biased for a double-gate effect.

A semiconductor device of embodiments includes: a silicon carbide layer including a trench, a n-type first SiC region, a p-type second SiC region on the first SiC region, a n-type third SiC region on the second SiC region, a fourth SiC region of p-type between the first trench and the first SiC region, and a fifth SiC region electrically connecting the second SiC region and the fourth SiC region; and a gate electrode in the trench. The first trench has a first region extending in a first direction, a second region continuous with the first region, and a third region continuous with the second region and extending in the first direction. The second width of the second region in the second direction is larger than the first width of the first region in the second direction. The fifth SiC region is disposed in the second direction of the second region.

An SOI wafer contains a compressively stressed buried insulator structure. In one example, the stressed buried insulator (BOX) may be formed on a host wafer by forming silicon oxide, silicon nitride and silicon oxide layers so that the silicon nitride layer is compressively stressed. Wafer bonding provides the surface silicon layer over the stressed insulator layer. Preferred implementations of the invention form MOS transistors by etching isolation trenches into a preferred SOI substrate having a stressed BOX structure to define transistor active areas on the surface of the SOI substrate. Most preferably the trenches are formed deep enough to penetrate through the stressed BOX structure and some distance into the underlying silicon portion of the substrate. The overlying silicon active regions will have tensile stress induced due to elastic edge relaxation.

A method for fabricating p-type field effect transistor (FET) includes the steps of first providing a substrate, forming a pad layer on the substrate, forming a well in the substrate, performing an ion implantation process to implant germanium ions into the substrate to form a channel region, and then conducting an anneal process to divide the channel region into a top portion and a bottom portion. After removing the pad layer, a gate structure is formed on the substrate and a lightly doped drain (LDD) is formed adjacent to two sides of the gate structure.

A semiconductor device includes a substrate; a fin protruding above the substrate, the fin including a compound semiconductor material that includes a semiconductor material and a first dopant, the first dopant having a different lattice constant than the semiconductor material, where a concentration of the first dopant in the fin changes along a first direction from an upper surface of the fin toward the substrate; a gate structure over the fin; a channel region in the fin and directly under the gate structure; and source/drain regions on opposing sides of the gate structure, the source/drain regions including a second dopant, where a concentration of the second dopant at a first location within the channel region is higher than that at a second location within the channel region, where the concentration of the first dopant at the first location is lower than that at the second location.

A semiconductor device includes: a first semiconductor layer of first conductivity type; a second semiconductor layer of first conductivity type provided on the first semiconductor layer; a first semiconductor region of second conductivity type provided on the second semiconductor layer; a second semiconductor region of first conductivity type provided on the first semiconductor region; a first electrode provided in a first trench, the first trench reaching the second semiconductor layer from above the first semiconductor region, the first electrode facing the first semiconductor region via a first insulating film; a second electrode provided in a second trench, the second trench reaching the second semiconductor layer from above the first semiconductor region, the second electrode facing the first semiconductor region via a second insulating film; a third electrode including a first electrode portion, a second electrode portion provided on the first electrode portion and a third electrode portion provided on the second electrode portion, the first electrode portion being provided between the first trench and the second trench, the first electrode portion reaching the first semiconductor region from above the second semiconductor region, the first electrode portion being electrically connected to the first semiconductor region and the second semiconductor region; a third semiconductor region provided between the third electrode and the second semiconductor region provided between the first insulating film and the third electrode, the third semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region; a fourth semiconductor region provided between the third electrode and the second semiconductor region provided between the second insulating film and the third electrode, the fourth semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region; and a fifth semiconductor region provided between the first semiconductor region and the third electrode, the fifth semiconductor region being provided apart from the third semiconductor region and the fourth semiconductor region, the fifth semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region.

A structure of semiconductor device is provided, including a substrate. First and second trench isolations are disposed in the substrate. A height of a portion of the substrate is between a top and a bottom of the first and second trench isolations. A gate insulation layer is disposed on the portion of the substrate between the first and second trench isolations. A first germanium (Ge) doped layer region is disposed in the portion of the substrate just under the gate insulation layer. A second Ge doped layer region is in the portion of the substrate, overlapping with the first Ge doped layer region to form a Ge gradient from high to low along a depth direction under the gate insulation layer. A fluorine (F) doped layer region is in the portion of the substrate, lower than and overlapping with the first germanium doped layer region.

A semiconductor device includes: a first semiconductor layer of first conductivity type; a second semiconductor layer of first conductivity type provided on the first semiconductor layer; a first semiconductor region of second conductivity type provided on the second semiconductor layer; a second semiconductor region of first conductivity type provided on the first semiconductor region; a first electrode provided in a first trench, the first trench reaching the second semiconductor layer from above the first semiconductor region, the first electrode facing the first semiconductor region via a first insulating film; a second electrode provided in a second trench, the second trench reaching the second semiconductor layer from above the first semiconductor region, the second electrode facing the first semiconductor region via a second insulating film; a third electrode including a first electrode portion, a second electrode portion provided on the first electrode portion and a third electrode portion provided on the second electrode portion, the first electrode portion being provided between the first trench and the second trench, the first electrode portion reaching the first semiconductor region from above the second semiconductor region, the first electrode portion being electrically connected to the first semiconductor region and the second semiconductor region; a third semiconductor region provided between the third electrode and the second semiconductor region provided between the first insulating film and the third electrode, the third semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region; a fourth semiconductor region provided between the third electrode and the second semiconductor region provided between the second insulating film and the third electrode, the fourth semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region; and a fifth semiconductor region provided between the first semiconductor region and the third electrode, the fifth semiconductor region being provided apart from the third semiconductor region and the fourth semiconductor region, the fifth semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region.