A quantum device includes a transistor structure section having a source, a drain, and a gate, one or more quantum dot structure sections in which a charge is localizable, and a quantum bit control current line configured to change a state of the charge in the quantum dot structure section.

The present invention provides a self-healing field-effect transistor (FET) device comprising a self-healing substrate and a self-healing dielectric layer, said substrate and said layer comprising a disulfide-containing poly(urea-urethane) (PUU) polymer, wherein the dielectric layer has a thickness of less than about 10 μm, a gate electrode, at least one source electrode, and at least one drain electrode, said electrodes comprising electrically conductive elongated nanostructures; and at least one channel comprising semi-conducting elongated nanostructures. Further provided is a method for fabricating the FET device.

Embodiments of the present disclosure includes a method of forming a semiconductor device. The method includes providing a substrate having a plurality of first semiconductor layers and a plurality of second semiconductor layers disposed over the substrate. The method also includes patterning the first semiconductor layers and the second semiconductor layers to form a first fin and a second fin, removing the first semiconductor layers from the first and second fins such that a first portion of the patterned second semiconductor layers becomes first suspended nanostructures in the first fin and that a second portion of the patterned second semiconductor layers becomes second suspended nanostructures in the second fin, and doping a threshold modifying impurity into the first suspended nanostructures in the first fin.

A semiconductor device includes a first PMOS transistor, a first NMOS transistor, and a second NMOS transistor connected to an output node of the first PMOS and NMOS transistors. The first PMOS transistor includes first nanowires, first source and drain regions on opposite sides of each first nanowire, and a first gate completely surrounding each first nanowire. The first NMOS transistor includes second nanowires, second source and drain regions on opposite sides of each second nanowire, and a second gate extending from the first gate and completely surrounding each second nanowire. The second NMOS transistor includes third nanowires, third source and drain regions on opposite sides of each third nanowire, and a third gate, separated from the first and second gates, and completely surrounding each third nanowire. A number of third nanowires is greater than that of first nanowires. The first and second gates share respective first and second nanowires.

Disclosed is a field-effect transistor and a method for manufacturing a field-effect transistor. The method comprises: forming an NMOSFET region and a PMOSFET region on a substrate; forming a hard mask on the NMOSFET region and the PMOSFET region, and patterning through the hard mask; forming a multiple of stacked nanowires in the NMOSFET region and a multiple of stacked nanowires in the PMOSFET region; forming a first array of nanowires in the NMOSFET region and a second array of nanowires in the PMOSFET region; and forming an interfacial oxide layer, a ferroelectric layer, and a stacked metal gate in sequence around each of the nanowires included in the first array and the second array. Wherein the NMOSFET region and the PMOSFET region are separated by shallow trench isolation.

A semiconductor device is provided. The semiconductor device includes a substrate and a plurality of nanowires. The substrate has an upper surface. The nanowires are stacked on the upper surface of the substrate along a first direction. The nanowires include a triangle in a cross section, and the nanowires include a plane extending along a second direction, a first down-slant facet on a (111) plane, and a second down-slant facet on an additional (111) plane.

Semiconductor structures and methods for crystalline junctionless transistors used in nonvolatile memory arrays are introduced. Various embodiments in accordance with this disclosure provide a method of fabricating a monolithic 3D cross-bar nonvolatile memory array with low thermal budget. The method incorporates crystalline junctionless transistors into nonvolatile memory structures by transferring a layer of doped crystalline semiconductor material from a seed wafer to form the source, drain, and connecting channel of the junctionless transistor.

In an embodiment, a device includes: a power rail contact; an isolation region on the power rail contact; a first dielectric fin on the isolation region; a second dielectric fin adjacent the isolation region and the power rail contact; a first source/drain region on the second dielectric fin; and a source/drain contact between the first source/drain region and the first dielectric fin, the source/drain contact contacting a top surface of the first source/drain region, a side surface of the first source/drain region, and a top surface of the power rail contact.

A semiconductor device according to the present disclosure includes a first source/drain epitaxial feature and a second source/drain epitaxial feature each having an outer liner layer and an inner filler layer, a plurality of channel members extending between the first source/drain epitaxial feature and the second source/drain epitaxial feature along a first direction, and a gate structure disposed over and around the plurality of channel members. The plurality of channel members are in contact with the outer liner layer and are spaced apart from the inner filler layer. The outer liner layer comprises germanium and boron and the inner filler layer comprises germanium and gallium.

Integrated circuit structures having backside gate cut or backside trench contact cut, and methods of fabricating integrated circuit structures having backside gate cut or backside trench contact cut, are described. For example, an integrated circuit structure includes a first sub-fin structure over a first stack of nanowires. A second sub-fin structure is over a second stack of nanowires. A first gate electrode is around the first stack of nanowires. A second gate electrode is around the second stack of nanowires. A dielectric structure is between the first gate electrode and the second gate electrode. The dielectric structure is continuous along an entirety of a height of the first gate electrode and the first sub-fin structure.