Structures and formation methods of a semiconductor device structure are provided. The method includes providing a substrate having a first fin, and the first fin has a channel region and a source/drain region. The method includes forming a stack structure over the first fin, and the stack structure includes a first semiconductor layer and a second semiconductor layer vertically stacked over the fin. The method also includes removing a portion of the second semiconductor layer in the channel region, and a portion of the first semiconductor layer is remaining in the channel region. The method further includes forming a cladding layer over the remaining first semiconductor material layer in the channel region to form a nanostructure, wherein the nanostructure has a dumbbell shape. The method includes forming a gate structure surrounding the nanostructure.

A method of chemically etching, comprising: providing a base layer, the base layer comprising a first section and a second section, the first section comprising a first material, the second section comprising a second material; providing a resist layer, wherein a first portion of the resist layer covers at least a portion of the first section of the base layer, and wherein a second portion of the resist layer covers at least a portion of the second section of the base layer; and exposing the first and second portions of the resist layer to a first chemical etchant, such that the first chemical etchant migrates through the first portion of the resist layer to react with the first material of the first section of the base layer and removes the first portion of the resist layer, and such that the second portion of the resist layer is not removed.

A semiconductor device includes first and second fins, first and second hafnium oxide layers, first and second cap layers, and first and second metal gate electrodes. The first and second fins protrude above a substrate and respectively have an n-channel region and a p-channel region. The first and second hafnium oxide layers wrap around the n-channel region and the p-channel region, respectively. The first and second cap layers wrap around the first and second annular hafnium oxide layers, respectively. The first and second cap layers are made of a same material that is lanthanum oxide, yttrium oxide, or strontium oxide. The first and second metal gate electrodes wrap around the first and second cap layers, respectively. The first and second metal gate electrodes have a same metal composition. The first and second gate dielectrics have a same dielectric composition.

The present disclosure further relates to nanostructures, in particular hybrid nanostructures with patterned growth of various layers for use in nanoscale electronic devices, such as hybrid semiconductor nanostructures with patterned growth and/or deposition of superconducting material for use in quantum devices. The presently disclosed method can be utilized for in-situ manufacturing of nanoscale electronic devices that have not been contaminated by ex-situ processes. One embodiment relates to a method for manufacturing a substrate for growth of crystalline nanostructures, the method comprising the steps of: depositing one or more layers of a crystal growth compatible dielectric material, such as silicon oxide, in a predefined pattern on the surface of a crystal growth compatible substrate to create a predefined etch pattern of said crystal growth compatible material, and selectively etching the substrate surface around said etch pattern to provide at least one under-etched platform which is vertically raised from the etched substrate surface.

A method for manufacturing a semiconductor device includes forming a source layer on a semiconductor substrate, forming a channel layer on the source layer, and forming a drain layer on the channel layer. The source, channel and drain layers are patterned into at least one fin, and a cap layer is formed on a lower portion of the at least one fin. The lower portion of the at least one fin includes the source layer and part of the channel layer. The method further includes forming a gate structure comprising a gate dielectric layer and a gate conductor on the at least one fin and on the cap layer. The cap layer is positioned between the lower portion of the at least one fin and the gate dielectric layer.

Ion-doped two-dimensional nanomaterials are made by inducing electronic carriers (electrons and holes) in a two-dimensional material using a captured ion layer at the surface of the material. The captured ion layer is stabilized using a capping layer. The induction of electronic carriers works in atomically-thin two-dimensional materials, where it induces high carrier density of at least 10.sup.14 carriers/cm.sup.2. A variety of novel ion-doped nanomaterials and p-n junction-based nanoelectronic devices are made possible by the method.

Methods for the manufacture of semiconductor devices constructed with three-dimensional (3D) single crystal silicon nano sheets integrated with two-dimensional (2D) materials are disclosed. A device may include a semiconductor material and having a first end and a second end doped with a first polarity; a seed material wrapping around the semiconductor material; a two-dimensional (2D) material around the seed material; an active gate around the 2D material; and a source/drain structure in contact with the first end and the second end of the semiconductor material and in contact with the 2D material, wherein the source/drain structure is doped with a second polarity opposite to the first polarity.

Gate-all-around integrated circuit structures having depopulated channel structures, and methods of fabricating gate-all-around integrated circuit structures having depopulated channel structures using multiple bottom-up oxidation approaches, are described. For example, an integrated circuit structure includes a vertical arrangement of nanowires. All nanowires of the vertical arrangement of nanowires are oxide nanowires. A gate stack is over the vertical arrangement of nanowires, around each of the oxide nanowires. The gate stack includes a conductive gate electrode.

Embodiments of the invention are directed to a method of performing fabrication operations to form a nanosheet field effect transistor (FET) device. The fabrication operations include forming a sacrificial structure over a substrate, wherein the sacrificial structure includes a central region, a first leg at a first end of the central region, and a second leg at a second end of the central region. A nanosheet stack is formed over the central region. An isolation material is deposited within a space that was occupied by the sacrificial structure to form a wrap-around bottom dielectric isolation (BDI) structure having a BDI central region, a first BDI leg at a first end of the BDI central region, and a second BDI leg at a second end of the BDI central region.

A layered heterostructure, comprising alternating layers of different semiconductors, wherein one of the atom species of one of the semiconductors has a faster diffusion rate along an oxidizing interface than an atom species of the other semiconductor at an oxidizing temperature, can be used to fabricate embedded nanostructures with arbitrary shape. The result of the oxidation will be an embedded nanostructure comprising the semiconductor having slower diffusing atom species surrounded by the semiconductor having the higher diffusing atom species. The method enables the fabrication of low- and multi-dimensional quantum-scale embedded nanostructures, such as quantum dots (QDs), toroids, and ellipsoids.