A semiconductor structure includes a power rail contact at least partially disposed between a first source/drain region of a first vertical fin structure and a second source/drain region of a second vertical fin structure. The power rail contact is in contact with a buried power rail disposed under the first and second vertical fin structures. The power rail contact is in contact with at least one of the first and second source/drain regions. A contact cap is disposed above the power rail contact.

A vertical field-effect transistor includes a substrate comprising a semiconductor material; a first set of fins formed from the semiconductor material and extending vertically with respect to the substrate; and a second set of fins extending vertically with respect to the substrate, wherein ones of the second set of fins abut ones of the first set of fins. The second set of fins comprises a dielectric material.

A semiconductor memory device disposed over a substrate includes a common electrode, a selector material layer surrounding the common electrode, and a plurality of phase change material layers in contact with the selector material layer.

A semiconductor die includes semiconductor substrate and interconnection structure. Interconnection structure includes first conductive lines, first conductive patterns, first pillar stacks, second pillar stacks, gate patterns. First conductive lines extend parallel to each other in first direction and are embedded in interlayer dielectric layer. First conductive patterns are disposed in row along first direction and are embedded in interlayer dielectric layer beside first conductive lines. First pillar stacks include first pairs of metallic blocks separated by first dielectric material blocks. Second pillar stacks include second pairs of metallic blocks separated by second dielectric material blocks. Each second pillar stack is electrically connected to respective first conductive pattern. Gate patterns extend substantially perpendicular to first conductive lines. Each gate pattern directly contacts one respective second pillar stack and extends over a group of first pillar stacks.

A test structure includes a plurality of word lines and a plurality of bit lines. A vertical gate-all-around (VGAA) transistor is formed at the intersection of each word line and each bit line. The test structure includes a first area and a second area. The second area is arranged outside the first area, the word lines in the first area and the word lines in the second area are disconnected, and the bit lines in the first area and the bit lines in the second area are disconnected. The plurality of VGAA transistors located in the first area form a test array, and a VGAA transistor located in the middle of the test array is a device to be tested.

A semiconductor structure and a method for manufacturing same are provided. The semiconductor structure includes: a substrate, and a first transistor and a second transistor protruding from the substrate. The first transistor at least includes a first doped region and a second doped region arranged from bottom to top. The second transistor at least includes a third doped region and a fourth doped region arranged from bottom to top. Herein, the first doped region and the third doped region have a first conductivity type, the second doped region and the fourth doped region have a second conductivity type, and a breakdown voltage of the first transistor is smaller than a breakdown voltage of the second transistor.

Vertical transport field-effect transistors are formed on active regions wherein the active regions each include a wrap-around metal silicide contact on vertically extending side walls of the active region. Such wrap-around contacts form self-aligned and reliable strapping for SRAM bottom nFET and pFET source/drain regions. Buried contacts of SRAM cells may be used to strap the wrap-around metal silicide contacts with the gates of inverters thereof. Wrap-around metal silicide contacts provide additional contacts for logic FETs and reduce parasitic bottom source/drain resistance.

A wide band gap semiconductor device includes a semiconductor layer, a trench formed in the semiconductor layer, first, second, and third regions having particular conductivity types and defining sides of the trench, and a first electrode embedded inside an insulating film in the trench. The second region integrally includes a first portion arranged closer to a first surface of the semiconductor layer than to a bottom surface of the trench, and a second portion projecting from the first portion toward a second surface of the semiconductor layer to a depth below a bottom surface of the trench. The second portion of the second region defines a boundary surface with the third region, the boundary region being at an incline with respect to the first surface of the semiconductor layer.

A semiconductor device includes an enhancement-mode first p-channel MISFET, an enhancement-mode second p-channel MISFET, a drain conductor electrically and commonly connected to the first p-channel MISFET and the second p-channel MISFET, a first source conductor electrically connected to a source of the first p-channel MISFET, a second source conductor electrically connected to a source of the second p-channel MISFET, and a gate conductor electrically and commonly connected to a gate of the first p-channel MISFET and a gate of the second p-channel MISFET.

A method of manufacturing a vertical memory device includes forming a first sacrificial layer on a substrate, the first sacrificial layer including a first insulating material, forming a mold including an insulation layer and a second sacrificial layer alternately and repeatedly stacked on the first sacrificial layer, the insulation layer and the second sacrificial layer including second and third insulating materials, respectively, different from the first insulating material, forming a channel through the mold and the first sacrificial layer, forming an opening through the mold and the first sacrificial layer to expose an upper surface of the substrate, removing the first sacrificial layer through the opening to form a first gap, forming a channel connecting pattern to fill the first gap, and replacing the second sacrificial layer with a gate electrode.