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 for forming spacers of a gate of a field-effect transistor is provided, including at least one step of forming a protective layer covering the gate; depositing a layer comprising carbon, said layer being disposed distant from said transistor; modifying the protective layer to form a modified protective layer; forming a protective film on the layer comprising carbon; removing the protective film on surfaces of the protective film that are perpendicular to a main implantation direction; selectively removing the layer comprising carbon; and at least one step of selectively removing the modified protective layer.

A structure includes a substrate and a tunnel field effect transistor (TFET). The TFET includes a source region disposed in the substrate having an overlying source contact, the source region containing first semiconductor material having a first doping type; a drain region disposed in the substrate having an overlying drain contact, the drain region containing second semiconductor material having a second, opposite doping type; and a gate structure that overlies a channel region between the source and the drain. The source region and the drain region are asymmetric with respect to one another such that one contains a larger volume of semiconductor material than the other one. A method is disclosed to fabricate a plurality of the TFETs using a plurality of spaced apart mandrels having spacers. A pair of the mandrels and the associated spacers is processed to form four adjacent TFETs without requiring intervening lithographic processes.

A semiconductor device with reinforced gate spacers and a method of fabricating the same. The semiconductor device includes low-k dielectric gate spacers adjacent to a gate structure. A high-k dielectric material is disposed over an upper surface of the low-k dielectric gate spacers to prevent unnecessary contact between the gate structure and a self-aligned contact structure. The high-k dielectric material may be disposed, if desired, over an upper surface of the gate structure to provide additional isolation of the gate structure from the self-aligned contact structure.

A method of forming a gate spacer in a vertical transistor includes depositing a gate spacer layer on a source layer and a sacrificial gate material on the gate spacer layer; etching a trench through the sacrificial gate material and the gate spacer and forming an epitaxial channel within the trench; removing a portion of the sacrificial gate material to expose a portion of the gate spacer layer and leave the sacrificial gate material arranged on sidewalls of the channel; depositing an ultra-low-k spacer material on the gate spacer layer such that the ultra-low-k spacer material contacts a sidewall of the sacrificial gate material; and removing remaining portions of the sacrificial gate material and replacing the sacrificial gate material with a metal gate.

Occurrence of short-channel characteristics and parasitic capacitance of a MOSFET on a SOI substrate is prevented. A sidewall having a stacked structure obtained by sequentially stacking a silicon oxide film and a nitride film is formed on a side wall of a gate electrode on the SOI substrate. Subsequently, after an epitaxial layer is formed beside the gate electrode, and then, the nitride film is removed. Then, an impurity is implanted into an upper surface of the semiconductor substrate with using the gate electrode and the epitaxial layer as a mask, so that a halo region is formed in only a region of the upper surface of the semiconductor substrate which is right below a vicinity of both ends of the gate electrode.

A semiconductor device that includes a gate structure on a channel region of a semiconductor device. Source and drain regions may be present on opposing sides of the channel region. The semiconductor device may further include a composite gate sidewall spacer present on a sidewall of the gate structure. The composite gate sidewall spacer may include a first composition portion having an air gap encapsulated therein, and a second composition portion that is entirely solid and present atop the first composition portion.

A replacement gate FinFET manufacturing process in which the source/drain regions, gate structure and gate spacer are all defined by utilizing a single sidewall image transfer technique is provided. In the present application, the source/drain region (i.e., area) are defined by a mandrel structure, while the area for the functional gate structure are defined by the distance between spacers that are located on a pair of neighboring mandrel structures. The gate spacer is defined by the spacer present on the mandrel structures. In some embodiments, semiconductor fin erosion due to gate and gate spacer formation can be reduced or even eliminated.

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 semiconductor device includes an isolation pattern on a substrate, the isolation pattern having a lower insulating pattern on the substrate, and a spacer to cover side surfaces of the lower insulating pattern, a vertical structure through the isolation pattern to contact the substrate, the vertical structure having a first semiconductor layer on the substrate, a lower end of the first semiconductor layer being at a lower level than a lower surface of the isolation pattern, a second semiconductor layer on the first semiconductor layer, and a third semiconductor layer on the second semiconductor layer, and a gate electrode crossing the vertical structure and extending over the isolation pattern.