A novel dielectric cap structure for VTFET device fabrication is provided. In one aspect, a method of forming a VTFET device includes: patterning fins in a substrate using fin hardmasks, including a first fin(s) and a second fin(s); depositing a liner over the fins and the fin hardmasks; selectively forming first hardmask caps on top of the fin hardmasks/liner over the first fin(s); forming first bottom source and drain at a base of the first fin(s) while the fin hardmasks/liner over the first fin(s) are preserved by the first hardmask caps; selectively forming second hardmask caps on top of the fin hardmasks/liner over the second fin(s); and forming second bottom source and drains at a base of the second fin(s) while the fin hardmasks/liner over the second fin(s) are preserved by the second hardmask caps. A device structure is also provided.

A band-shaped Si pillar having a mask material layer on the top portion thereof is formed on a P+ layer. SiGe layers having mask material layers on the top portions thereof are then formed in contact with the side surfaces of the band-shaped Si pillar and the surfaces of N+ layers and the P+ layer. Si layers having mask material layers on the top portions thereof are then formed in contact with the side surfaces of the SiGe layers and the surfaces of the N+ layers. The outer peripheries of the bottom portions of the Si layers are then removed using the mask material layers as a mask to form band-shaped Si pillars. The mask material layers and the SiGe layers are then removed. Si pillars separated in the Y direction are then formed in the band-shaped Si pillars.

Embodiments relate to a semiconductor structure and a method for fabricating the same. The method includes: providing a substrate, a first trench being formed in the substrate; forming a protective layer in the first trench, the protective layer covering a side wall and a bottom of the first trench; etching the protective layer and the substrate at the bottom of the first trench to form second trenches; forming a passivation layer at a bottom of each of the second trenches; and etching a side wall of each of the second trenches to form a groove, and forming a dielectric layer in the groove. The method can eliminate a process of forming a bit line contact structure, thereby reducing resistance of a bit line and simplifying fabrication processes of the bit line.

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.

Embodiments of the disclosure provide a semiconductor structure and a method for forming the same. The method includes: providing a semiconductor substrate including a plurality of active pillars arranged at intervals; etching the active pillar to form an annular groove, in which the annular groove does not expose a top surface and a bottom surface of the active pillar; and forming a first semiconductor layer in the annular groove to form the semiconductor structure; in which a band gap of the first semiconductor layer is smaller than a band gap of the active pillar.

A semiconductor structure and a method for manufacturing a semiconductor structure are provided, which relate to the technical field of semiconductors. The semiconductor structure includes a substrate and a plurality of first conductive layers. The substrate includes a plurality of first trenches extending in a first direction and a plurality of second trenches extending in a second direction. A plurality of active pillars are provided between the plurality of first trenches and the plurality of second trenches. The first direction intersects with the second direction. Each of the plurality of first conductive layers is arranged on each of sidewalls, which are arrayed in the first direction, of a respective one of the plurality of active pillars.

A semiconductor structure includes a base in which a first doped region is provided and an active pillar group arranged in the first doped region. The active pillar group includes four active pillars arranged in an array. At least one of the active pillars is provided with a notch, which faces at least one of a row centerline or a column centerline of the active pillar group.

A semiconductor structure and a method for manufacturing a semiconductor structure are provided. The semiconductor structure includes: a substrate, first gate structures, second gate structures, and a covering layer. The substrate includes semiconductor channels spaced apart from each other and arranged at a top portion of the substrate and extending in a vertical direction. Each first gate structure is arranged in a first area of a respective semiconductor channel and is arranged around the respective semiconductor channel. Each second gate structure is arranged in a second area of a respective semiconductor channel and includes a ring structure and at least one bridge structure. The covering layer is arranged in a spaced area between any two adjacent semiconductor channels. The covering layer includes first interconnecting holes extending in the vertical direction.

A semiconductor structure and a method for manufacturing a semiconductor structure are provided. The method for manufacturing the semiconductor structure includes: a substrate is provided: a plurality of semiconductor channels arrayed in a first direction and a second direction are formed on the substrate: a plurality of bit lines extending in the first direction are formed, in which the bit lines is located in the substrate: and a plurality of word lines extending in the second direction are formed, in which two word lines adjacent to each other in the first direction are spaced apart from each other in a direction perpendicular to a surface of the substrate: and a sidewall conductive layer is formed, in which the sidewall conductive layer is located above one of the two word lines adjacent to each other, and is arranged in the same layer as the other of the two word lines.

A semiconductor device includes a substrate, and a plurality of active regions disposed over the substrate. The plurality of active regions have a first total area. One or more inactive regions are also disposed over the substrate. The one or more inactive regions have a second total area. The second total area is greater than or equal to 1.5 times the first total area. The active regions may be formed in an epitaxial layer formed over the substrate. A plurality of cells of an active device may be disposed in the plurality of active regions. The inactive regions may include only structures that do not dissipate substantial power when the semiconductor device is functioning as it is designed to function.