A semiconductor device having good characteristics without variation and a method of manufacturing the same are provided. A part of a conductive layer for a floating gate is removed by using a spacer insulating film, a first insulating film, and a second insulating film as a mask. A floating gate having a tip portion is formed from the conductive layer for the floating gate, and a part of an insulating layer for a gate insulating film is exposed from the floating gate. The tip portion of the floating gate is further exposed by selectively removing the second insulating film among the second insulating film, the insulating layer for the gate insulating film, and the spacer insulating film.

A method for forming a nanowire device comprises depositing a hard mask on portions of a silicon substrate having a <110> orientation wherein the hard mask is oriented in the <112> direction, etching the silicon substrate to form a mandrel having (111) faceted sidewalls; forming a layer of insulator material on the substrate; forming a sacrificial stack comprising alternating layers of sacrificial material and dielectric material disposed on the layer of insulator material and adjacent to the mandrel; patterning and etching the sacrificial stack to form a modified sacrificial stack adjacent to the mandrel and extending from the mandrel; removing the sacrificial material from the modified sacrificial stack to form growth channels; epitaxially forming semiconductor in the growth channels; and etching the semiconductor to align with the end of the growth channels and form a semiconductor stack comprising alternating layers of dielectric material and semiconductor material.

A lateral epitaxial growth process is employed to facilitate the fabrication of a semiconductor structure including a stack of suspended III-V or germanium semiconductor nanowires that are substantially defect free. The lateral epitaxial growth process is unidirectional due to the use of masks to prevent epitaxial growth in both directions, which would create defects when the growth fronts merge. Stacked sacrificial material nanowires are first formed, then after masking and etching process to reveal a semiconductor seed layer, the sacrificial material nanowires are removed, and III-V compound semiconductor or germanium epitaxy is performed to fill the void previously occupied by the sacrificial material nanowires.

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.

A method of fabricating a vertical field effect transistor comprising that includes forming openings through a spacer material to provide fin structure openings to a first semiconductor material, and forming an inner spacer liner on sidewalls of the fin structure openings. A channel semiconductor material is epitaxially formed on a surface of the first semiconductor material filling at least a portion of the fin structure openings. The spacer material is recessed with an etch that is selective to the inner spacer liner to form a first spacer. The inner spacer liner is removed selectively to the channel semiconductor material. A gate structure on the channel semiconductor material, and a second semiconductor material is formed in contact with the channel semiconductor material.

A method for preserving interlevel dielectric in a gate cut region includes recessing a dielectric fill to expose cap layers of gate structures formed in a device region and in a cut region and forming a liner in the recess on top of the recessed dielectric fill. The liner includes a material to provide etch selectivity to protect the dielectric fill. The gate structures in the cut region are recessed to form a gate recess using the liner to protect the dielectric fill from etching. A gate material is removed from within the gate structure using the liner to protect the dielectric fill from etching. A dielectric gap fill is formed to replace the gate material and to fill the gate recess in the cut region.

Field effect transistors include a stack of nanosheets of vertically arranged channel layers. A source and drain region is positioned at respective ends of the vertically arranged channel layers. A gate stack is formed over, around, and between the vertically arranged channel layers. The transistor includes a plurality of internal spacers, each formed between the gate stack and a respective source or drain region, with at least one pair of spacers being positioned above an uppermost channel layer.

A method for filling gaps between structures includes forming a plurality of high aspect ratio structures adjacent to one another with gaps, forming a first dielectric layer on tops of the structures and conformally depositing a spacer dielectric layer over the structures. The spacer dielectric layer is removed from horizontal surfaces and a protection layer is conformally deposited over the structures. The gaps are filled with a flowable dielectric, which is recessed to a height along sidewalls of the structures by a selective etch process such that the protection layer protects the spacer dielectric layer on sidewalls of the structures. The first dielectric layer and the spacer dielectric layer are exposed above the height using a higher etch resistance than the protection layer to maintain dimensions of the spacer layer dielectric through the etching processes. The gaps are filled by a high density plasma fill.

A method of fabricating a semiconductor transistor and the semiconductor transistor include a source region and a drain region within a substrate. The method includes forming a gate above the substrate, forming a source contact above the source region and a drain contact above the drain region, and forming air spacers within a dielectric between the gate and each of the source contact and the drain contact. Metal caps are formed on the source contact and the drain contact, and a gate cap is formed between the dielectric and at least a portion of a bottom surface of higher-level contacts, which are contacts formed above the source contact and the drain contact.

A semiconductor device includes a substrate including a fin-shaped active region that protrudes from the substrate; a gate insulating film covering a top surface and both side walls of the fin-shaped active region; a gate electrode on the top surface and the both side walls of the fin-shaped active region and covering the gate insulating film; one pair of insulating spacers on both side walls of the gate electrode; and a source region and a drain region on the substrate and respectively located on sides of the gate electrode. The source region and the drain region form a source/drain pair. The one pair of insulating spacers include protrusions that protrude from upper portions of the one pair of insulating spacers toward the gate electrode.