Abstract: A technique relates to fabricating a semiconductor device. A contact trench is formed in an inter-level dielectric layer. The contact trench creates an exposed portion of a semiconductor substrate through the inter-level dielectric layer. A gate stack is on the semiconductor substrate, and the inter-level dielectric layer is adjacent to the gate stack and the semiconductor substrate. A source/drain region is formed in the contact trench such that the source/drain region is on the exposed portion of the semiconductor substrate. Tin is introduced in the source/drain region to form an alloyed layer on top of the source/drain region, and the alloyed layer includes the tin and a source/drain material of the source/drain region. A trench layer is formed in the contact trench such that the trench layer is on top of the alloyed layer. A metallic liner layer is formed on the trench layer and the inter-level dielectric layer.

Abstract: Methods of fabrication and semiconductor structures includes vertical transport field effect transistors (VTFETs) including a top source/drain extension formed with a sacrificial doped layer. The sacrificial doped layer provides the doping source to form the extension and protects the top of the fin during fabrication so as to prevent thinning, among other advantages.

Abstract: A method of forming a semiconductor structure includes forming a plurality of fins over a top surface of a substrate, and forming one or more vertical transport field-effect transistors from the plurality of fins, the plurality of fins providing channels for the one or more vertical transport field-effect transistors. The method also includes forming a gate stack for the one or more vertical transport field-effect transistors surrounding at least a portion of the plurality of fins, the gate stack including a gate dielectric formed over the plurality of fins, a work function metal layer formed over the gate dielectric, and a gate conductor formed over the work function metal layer. The gate stack comprises a box profile in an area between at least two adjacent ones of the plurality of fins.

Abstract: A method of forming a semiconductor device that includes forming a vertically orientated channel in a semiconductor fin structure that is present on a supporting substrate; and depositing a doped amorphous semiconductor material on an upper surface of the semiconductor fin structure that is opposite a base surface of the semiconductor fin structure that is in contact with the supporting substrate. The method further includes recrystallizing the doped amorphous semiconductor material with an anneal duration for substantially a millisecond duration or less to provide a doped polycrystalline source and/or drain region at the upper surface of the semiconductor fin structure.

Abstract: A method of forming gate structures to a nanosheet device that includes forming at least two stacks of nanosheets, wherein each nanosheet includes a channel region portion having a gate dielectric layer present thereon. The method may further include forming a dual metal layer scheme on the gate dielectric layer of each nanosheet. The dual metal layer scheme including an etch stop layer of a first composition and a work function adjusting layer of a second composition, wherein the etch stop layer has a composition that provides that the work function adjusting layer is removable by a wet etch chemistry that is selective to the etch stop layer.

Abstract: According to an embodiment of the present invention, a method for forming a semiconductor device includes pattering a first fin in a semiconductor substrate, and forming a liner layer over the first fin. The method further includes removing a first portion of the liner layer, and removing a portion of the exposed semiconductor substrate to form a first cavity. The method also includes performing an isotropic etching process to remove portions of the semiconductor substrate in the first cavity and form a first undercut region below the liner layer, growing a first epitaxial semiconductor material in the first undercut region and the first cavity, and performing a first annealing process to drive dopants from the first epitaxial semiconductor material into the first fin to form a first source/drain layer under the first fin and in portions of the semiconductor substrate.

Abstract: Low temperature epitaxial silicon deposition for forming the top source or drain regions of VTFET structures. The methods generally include epitaxially growing a silicon layer with a dopant at a temperature less 500° C. on a first surface and an additional surface to form a single crystalline silicon on the first surface and a polysilicon or amorphous silicon on the additional surface. The epitaxially grown silicon layer is then exposed to an etchant include HCl and germane at a temperature less than 500° C. for a period of time effective to selectively remove the polysilicon/amorphous silicon on the additional surface and form a germanium diffused region on and in an outer surface of the single crystalline silicon formed on the first surface.

Abstract: A method for forming a semiconductor device includes forming a fins on a substrate, forming a sacrificial gate stack over a channel region of the fins, a source/drain region with a first material on the fins, a first cap layer with a second material over the source/drain region, and a second cap layer with a third material on the first cap layer. A dielectric layer is deposited over the second cap layer. The sacrificial gate stack is removed to expose a channel region of the fins. A gate stack is formed over the channel region of the fins. A portion of the dielectric layer is removed to expose the second cap layer. The second cap layer and the first cap layer are removed to expose the source/drain region. A conductive material is deposited on the source/drain region.

Abstract: A method of forming a fin field effect transistor device is provided. The method includes forming a plurality of vertical fins on a substrate. The method further includes forming a bottom source/drain layer adjacent to the plurality of vertical fins, and growing a doped layer on the bottom source/drain layer and sidewalls of the plurality of vertical fins. The method further includes forming a dummy gate liner on the doped layer and the bottom source/drain layer, and forming a dummy gate fill on the dummy gate liner. The method further includes forming a protective cap layer on the dummy gate fill, and removing a portion of the protective cap layer to expose a top surface of the plurality of vertical fins.

Abstract: A method of forming a semiconductor structure includes forming a substrate, the substrate having a first portion with a first height and second recessed portions with a second height less than the first height. The method also includes forming embedded source/drain regions disposed over top surfaces of the second recessed portions of the substrate, and forming one or more fins from a portion of the substrate disposed between the embedded source/drain regions, the one or more fins providing channels for fin field-effect transistors (FinFETs). The method further includes forming a gate stack disposed over the one or more fins, and forming inner oxide spacers disposed between the gate stack and the source/drain regions.

Abstract: Integrated chips and methods of forming the same include etching a first stack of layers in a first region and etching a second stack of layers in a second region. The first stack of layers includes a first semiconductor layer having a first thickness over a first sacrificial layer having a second thickness. Etching the first stack of layers removes the first sacrificial layer from the first stack of layers and creates a first gap. The second stack of layers includes a second semiconductor layer having a third thickness over a second sacrificial layer having a fourth thickness. Etching the second stack of layers removes the second sacrificial layer from the second stack of layers and to create a second gap. A dielectric material fills the first gap and the second gap.

Abstract: Various methods and structures for fabricating a plurality of vertical fin FETs on the same semiconductor substrate in which a first gate length of a first gate in a first vertical fin FET is less than a second gate length of a second gate in a second vertical fin FET. A difference in gate lengths between different vertical fin FETs can be precisely fabricated by using atomic layer silicon germanium epitaxy. Gate length offset is formed at a bottom source/drain junction region of each vertical fin FET transistor, which allows downstream processing for all vertical fin FET transistors to be the same.

Abstract: A method for manufacturing a semiconductor device includes forming a plurality of fins on a semiconductor substrate. In the method, sacrificial spacer layers are formed on the plurality of fins, and portions of the semiconductor substrate located under the sacrificial spacer layers and located at sides of the plurality of fins are removed. Bottom source/drain regions are grown in at least part of an area where the portions of the semiconductor substrate were removed, and sacrificial epitaxial layers are grown on the bottom source/drain regions. The method also includes diffusing dopants from the bottom source/drain regions and the sacrificial epitaxial layers into portions of the semiconductor substrate under the plurality of fins. The sacrificial epitaxial layers are removed, and bottom spacers are formed in at least part of an area where the sacrificial epitaxial layers were removed.

Abstract: Devices and methods are provided to fabricate nanosheet field-effect transistor devices having dummy nanosheet channel layers disposed above active nanosheet channel layers to protect the active nanosheet channel layers from oxidation during work function metal patterning processes that are implemented as part of a multi-threshold voltage process module. The dummy nanosheet channel layers have a reduced thickness so that the dummy nanosheet layers do not function as active channel layers of the nanosheet field-effect transistor devices. The dummy nanosheet channel layers serve as an oxygen infusion blocking layers to protect the active nanosheet channel layers from being infused with oxygen and oxidized by a directional plasma etch process performed during a work function metal patterning process.

Abstract: In an embodiment, this invention relates to a vertical field-effect transistor component including a bottom source-drain layer and a method of creating the same. The method of forming a bottom source-drain layer of a vertical field-effect transistor component can comprise forming an anchor structure on a substrate. A sacrificial layer can be deposited on a middle region of the substrate and a channel layer can be deposited on the sacrificial layer. A plurality of vertical fins can be formed on the substrate and the sacrificial layer can be removed such that the plurality of vertical fins in the middle region form a plurality of floating fins having a gap located between the plurality of floating fins and the substrate. The bottom source-drain layer can then be formed such that the bottom source-drain layer fills in the gap.

Abstract: A method of forming stacked fin field effect devices is provided. The method includes forming a layer stack on a substrate, wherein the layer stack includes a first semiconductor layer on a surface of the substrate, a second semiconductor layer on the first semiconductor layer, a third semiconductor layer on the second semiconductor layer, a separation layer on the third semiconductor layer, a fourth semiconductor layer on the separation layer, a fifth semiconductor layer on the fourth semiconductor layer, and a sixth semiconductor layer on the fifth semiconductor layer. The method further includes forming a plurality of channels through the layer stack to the surface of the substrate, and removing portions of the second semiconductor layer and fifth semiconductor layer to form lateral grooves.

Abstract: A method of forming stacked fin field effect devices is provided. The method includes forming a layer stack on a substrate, wherein the layer stack includes a first semiconductor layer on a surface of the substrate, a second semiconductor layer on the first semiconductor layer, a third semiconductor layer on the second semiconductor layer, a separation layer on the third semiconductor layer, a fourth semiconductor layer on the separation layer, a fifth semiconductor layer on the fourth semiconductor layer, and a sixth semiconductor layer on the fifth semiconductor layer. The method further includes forming a plurality of channels through the layer stack to the surface of the substrate, and removing portions of the second semiconductor layer and fifth semiconductor layer to form lateral grooves.

Abstract: A method of forming a vertical fin field effect transistor (vertical finFET) with two concentric gate structures, including forming one or more tubular vertical fins on a substrate, forming a first gate structure around an outer wall of at least one of the one or more tubular vertical fins, and forming a second gate structure within an inner wall of at least one of the one or more tubular vertical fins having the first gate structure around the outer wall.

Abstract: Techniques for forming bottom source and drain extensions in VTFET devices are provided. In one aspect, a method of forming a VTFET device includes: patterning fins in a wafer; forming a liner at a base of the fins having a higher diffusivity for dopants than the fins; forming sidewall spacers alongside an upper portion of the fins; forming bottom source/drains on the liner at the base of the fins including the dopants; annealing the wafer to diffuse the dopants from the bottom source/drains, through the liner, into the base of the fins to form bottom extensions; removing the sidewall spacers; forming bottom spacers on the bottom source/drains; forming gate stacks alongside the fins above the bottom spacers; forming top spacers above the gate stacks; and forming top source/drains above the top spacers at tops of the fins. A VTFET device is also provided.

Abstract: After forming a gate structure over a semiconductor fin that extends upwards from a semiconductor substrate portion, a sigma cavity is formed within the semiconductor fin on each side of the gate structure. A semiconductor buffer region composed of an un-doped stress-generating semiconductor material is epitaxially growing from faceted surfaces of the sigma cavity. Finally, a doped semiconductor region composed of a doped stress-generating semiconductor material is formed on the semiconductor buffer region to completely fill the sigma cavity. The doped semiconductor region is formed to have substantially vertical sidewalls for formation of a uniform source/drain junction profile.