Provided are a semiconductor structure and a method for manufacturing the same. The semiconductor structure includes: a base; a bit line; and a semiconductor channel including a first doped region, a channel region, and a second doped region that are sequentially arranged, where the first doped region contacts the bit line, and the first doped region, the channel region, and the second doped region are doped with first-type doped ions. The channel region is further doped with second-type doped ions, enabling a concentration of majority carriers in the channel region to be less than a concentration of majority carriers in the first doped region and a concentration of majority carriers in the second doped region. The first-type doped ions are one of N-type ions or P-type ions, and the second-type doped ions are the other of N-type ions or P-type ions.

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 includes a substrate, a gate structure, a cover layer and a first sacrificial structure. The substrate includes discrete semiconductor channels arranged at a top of the substrate. The gate structure is disposed in a middle region of a semiconductor channel, and includes a ring structure and a bridge structure. The ring structure encircles the semiconductor channel, and the bridge structure penetrates through the semiconductor channel and extends to an inner wall of the ring structure along a penetrating direction. The cover layer is located between adjacent semiconductor channels, and includes a first communication hole. The first sacrificial structure is located on the cover layer, and includes a second communication hole. An inner sidewall of the second communication hole has an irregular shape.

A semiconductor structure includes a substrate, and a plurality of first semiconductor columns, a storage structure, a plurality of transistors and a first protective layer located above the substrate. The plurality of first semiconductor columns are arranged in array in first and second directions. Each first semiconductor column includes a first part and a second part located on same. The second part includes a bottom portion, an intermediate portion and a top portion. The first direction and the second direction intersect with each other and are both parallel to top surface of the substrate. The storage structure surrounds sidewalls of the first parts. The first protective layer surrounds sidewalls of the top portions of the second parts. A channel structure of each transistor is located in the intermediate portion of the second part, and an extending direction of the channel structure is the same as that of the second part.

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 structure and a method for manufacturing the same are provided. The semiconductor structure includes: a substrate, a dielectric layer, a first gate structure and a second gate structure. The substrate includes discrete semiconductors arranged at a top of the substrate and extending in a vertical direction. The first gate structure is arranged in a first region of the semiconductor pillar and surrounds the semiconductor pillar. The second gate structure is arranged in a second region of the semiconductor pillar and includes a ring structure and at least one bridge structure. The ring structure surrounds the semiconductor pillar, and the at least one bridge structure penetrates through the semiconductor pillar and extends to an inner wall of the ring structure in a penetrating direction. The dielectric layer is located between the first gate structure and the semiconductor pillar, and between the second gate structure and the semiconductor pillar.

Three-dimensional dynamic random-access memory (3D DRAM) structures and methods of formation of same are provided herein. In some embodiments, a 3D DRAM stack can include alternating silicon (Si) layers and silicon germanium (SiGe) layers. Each of the Si layers may have a height greater than a height of each of the SiGe layers. Methods and systems for formation of such structures are further provided.

A semiconductor device and a formation method thereof are provided. The semiconductor device includes: a semiconductor substrate, where a plurality of columnar active areas are formed on the semiconductor substrate, the plurality of columnar active areas are spaced apart by a plurality of first trenches extending along a first direction and a plurality of second trenches extending along a second direction; a plurality of third trenches positioned in the semiconductor substrate at bottoms of the second trenches, where the third trenches are recessed to bottoms of the columnar active areas, and a bottom surface of a given one of the third trenches is higher than a bottom surface of the given first trench; and a plurality of metal silicide bit lines extending along the first direction in the semiconductor substrate positioned at the bottoms of the plurality of third trenches and the bottoms of the plurality of columnar active areas.

A semiconductor structure includes a base, a dielectric layer, a gate structure, and a covering layer. The base includes discrete semiconductor pillars. The semiconductor pillars are disposed at the top of the base and extend in a vertical direction. The dielectric layer covers the sidewall of the semiconductor pillar. The gate structure is disposed in the middle area of the semiconductor pillar. The gate structure includes a gate-all-around structure, the gate-all-around surrounding the semiconductor pillar. A first part of the dielectric layer is disposed between the gate structures and the semiconductor pillars. The covering layer covers the top of the semiconductor pillar and part of the sidewall close to the top. The material of the covering layer includes a boron-containing compound.