A method of fabricating a semiconductor memory device includes etching a substrate that forms a trench that crosses active regions of the substrate, forming a gate insulating layer on bottom and side surfaces of the trench, forming a first gate electrode on the gate insulating layer that fills a lower portion of the trench, oxidizing a top surface of the first gate electrode where a preliminary barrier layer is formed, nitrifying the preliminary barrier layer where a barrier layer is formed, and forming a second gate electrode on the barrier layer that fills an upper portion of the trench.

Disclosed are semiconductor devices and methods of manufacturing the same. The method comprises forming an active structure including a plurality of active patterns, a device isolation layer defining the active patterns, and a gate structure across the active patterns and extending in a first direction, forming a first mask pattern on the active structure, and forming a trench by using the first mask pattern as an etching mask to pattern the active structure. Forming the first mask pattern comprises forming in a first mask layer a plurality of first openings extending in a second direction intersecting the first direction, and forming in the first mask layer a plurality of second openings extending in a third direction intersecting the first and second directions.

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.

Devices and methods that can facilitate hybrid under-bump metallization components are provided. According to an embodiment, a device can comprise an under-bump metallization component that can comprise a superconducting interconnect component and a solder wetting component. The device can further comprise a solder bump that can be coupled to the superconducting interconnect component and the solder wetting component. In some embodiments, the superconducting interconnect component can comprise a hermetically sealed superconducting interconnect component.

A method includes forming a dummy gate stack, forming a dielectric layer, with the dummy gate stack located in the dielectric layer, removing the dummy gate stack to form a opening in the dielectric layer, forming a metal layer extending into the opening, and etching back the metal layer. The remaining portions of the metal layer in the opening have edges lower than a top surface of the dielectric layer. A conductive layer is selectively deposited in the opening. The conductive layer is over the metal layer, and the metal layer and the conductive layer in combination form a replacement gate.

A semiconductor structure includes a material stack located on a surface of a semiconductor substrate. The material stack includes, from bottom to top, a silicon germanium alloy portion that is substantially relaxed and defect-free and a semiconductor material pillar that is defect-free. A dielectric material structure surrounds sidewalls of the material stack and is present on exposed portions of the semiconductor substrate.

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.

A conductive layer is formed between a metal gate structure, which includes a high-k gate dielectric layer and a gate electrode, and a contact feature. The conductive layer can be selectively deposited on a top surface of the gate electrode or, alternatively, non-selectively formed on the top surface of the gate electrode and the gate dielectric layer by controlling, for example, time of deposition. The conductive layer can have a bottom portion embedded into the gate electrode. The conductive layer and the contact feature can include the same composition, though they may be formed using different deposition techniques.

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.

A method of fabricating a semiconductor memory device includes etching a substrate that forms a trench that crosses active regions of the substrate, forming a gate insulating layer on bottom and side surfaces of the trench, forming a first gate electrode on the gate insulating layer that fills a lower portion of the trench, oxidizing a top surface of the first gate electrode where a preliminary barrier layer is formed, nitrifying the preliminary barrier layer where a barrier layer is formed, and forming a second gate electrode on the barrier layer that fills an upper portion of the trench.