Provided is a semiconductor structure with shared gated devices. The semiconductor structure comprises a substrate and a bottom dielectric isolation (BDI) layer on top of the substrate. The structure further comprises a pFET region that includes a p-doped Source-Drain epitaxy material and a first nanowire matrix above the BDI layer. The structure further comprises an nFET region that includes a n-doped Source-Drain epitaxy material and a second nanowire matrix above the BDI layer. The structure further comprises a conductive gate material on top of a portion of the first nanowire matrix and the second nanowire matrix. The structure further comprises a vertical dielectric pillar separating the pFET region and the nFET region. The vertical dielectric pillar extends downward through the BDI layer into the substrate. The vertical dielectric pillar further extends upward through the conductive gate material to a dielectric located above the gate region.

A method comprises forming a first fin including alternating first channel layers and first sacrificial layers and a second fin including alternating second channel layers and second sacrificial layers, forming a capping layer over the first and the second fin, forming a dummy gate stack over the capping layer, forming source/drain (S/D) features in the first and the second fin, removing the dummy gate stack to form a gate trench, removing the first sacrificial layers and the capping layer over the first fin to form first gaps, removing the capping layer over the second fin and portions of the second sacrificial layers to from second gaps, where remaining portions of the second sacrificial layers and the capping layers form a threshold voltage (V.sub.t) modulation layer, and forming a metal gate stack in the gate trench, the first gaps, and the second gaps.

Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises a first semiconductor stack and a second semiconductor stack over a substrate, wherein each of the first and second semiconductor stacks includes semiconductor layers stacked up and separated from each other; a dummy spacer between the first and second semiconductor stacks, wherein the dummy spacer contacts a first sidewall of each semiconductor layer of the first and second semiconductor stacks; and a gate structure wrapping a second sidewall, a top surface, and a bottom surface of each semiconductor layer of the first and second semiconductor stacks.

A semiconductor device may include a semiconductor fin, a source/drain region extending from the semiconductor fin, and a gate electrode over the semiconductor fin. The semiconductor fin may include a first well and a channel region over the first well. The first well may have a first dopant at a first dopant concentration and the channel region may have the first dopant at a second dopant concentration smaller than the first dopant concentration. The first dopant concentration may be in range from 10.sup.17 atoms/cm.sup.3 to 10.sup.19 atoms/cm.sup.3.

Novel semiconductors and fabrication techniques are provided. In various embodiments, a semiconductor includes a source, a drain, a first gate, a second gate, and a channel. The second gate is electrically coupled to the first gate. The first gate and the second gate are configured to control current between the source and the drain. The channel is in contact with the first gate and the second gate. The channel is configured such that the current flows through the channel. Other aspects, embodiments, and features are also claimed and described.

A method for forming a semiconductor device structure and an apparatus for heating a semiconductor substrate are provided. The method includes spin coating a material layer over a semiconductor substrate. The method also includes heating the material layer by using a first heater above the semiconductor substrate and a second heater below the semiconductor substrate.

An integrated circuit device includes a first gate stack formed on a first high dielectric layer and comprising a first work function adjustment metal containing structure and a second gate stack formed on a second high dielectric layer and comprising a second work function adjustment metal containing structure having an oxygen content that is greater than that of the first work function adjustment metal containing structure.

A method for fabricating a gate stack of a semiconductor device comprises forming a first dielectric layer over a channel region of the device, forming a first nitride layer over the first dielectric layer, forming a first gate metal layer over the first nitride layer, forming a capping layer over the first gate metal layer, removing portions of the capping layer and the first gate metal layer to expose a portion of the first nitride layer in a p-type field effect transistor (pFET) region of the gate stack, depositing a scavenging layer on the first nitride layer and the capping layer, depositing a second nitride layer on the scavenging layer, and depositing a gate electrode material on the second nitride layer.

A semiconductor device can be reduced in size. The semiconductor device has a first conductivity type p type well layer extending in the X direction of the main surface of a semiconductor substrate; a reference potential wire coupled with the p type well layer, and extending in the X direction; first and second active regions arranged on the opposite sides of the reference potential wire in the Y direction; and a gate electrode layer extending in the Y direction in such a manner as to cross with the first and second active regions . Then, the gate electrode layer has a first gate electrode of a second conductivity type at the crossing part with the first active region, a second gate electrode of the second conductivity type at the crossing part with the second active region, and a non-doped electrode between the first gate electrode and the second gate electrode.

The present disclosure describes a fin-like field-effect transistor (FinFET). The device includes one or more fin structures over a substrate, each with source/drain (S/D) features and a high-k/metal gate (HK/MG). A first HK/MG in a first gate region wraps over an upper portion of a first fin structure, the first fin structure including an epitaxial silicon (Si) layer as its upper portion and an epitaxial growth silicon germanium (SiGe), with a silicon germanium oxide (SiGeO) feature at its outer layer, as its middle portion, and the substrate as its bottom portion. A second HK/MG in a second gate region, wraps over an upper portion of a second fin structure, the second fin structure including an epitaxial SiGe layer as its upper portion, an epitaxial Si layer as it upper middle portion, an epitaxial SiGe layer as its lower middle portion, and the substrate as its bottom portion.