A semiconductor structure, a method for manufacturing the same and a memory are provided. The semiconductor structure includes a substrate, multiple semiconductor pillars, memory structures, and multiple transistors. The multiple semiconductor pillars are arrayed along a first direction and a second direction. Each semiconductor pillar includes a first portion and a second portion on the first portion. The memory structure includes a first electrode layer, a dielectric layer and a second electrode layer. The first electrode layers cover sidewalls of the first portions and are located in first filling regions arranged at intervals. Each first filling region surrounds a sidewall of the first portion. The dielectric layers cover at least surfaces of the first electrode layers. The second electrode layers cover surfaces of the dielectric layers. Channel structures of the transistors are located in the second portions, and extend in a same direction as the second portions.

A semiconductor structure includes: a substrate, a first gate structure, and a second gate structure. The substrate includes: discrete first semiconductor pillars arranged at a top of the substrate and extending in a vertical direction; and a second semiconductor pillar and a third semiconductor pillar extending in the vertical direction, the second and third semiconductor pillars are provided at a top of each first semiconductor pillar. The first gate structure is arranged in a middle region of the first semiconductor pillar and surrounds the first semiconductor pillar. The second gate structure is arranged in a middle region of the second semiconductor pillar and of the third semiconductor pillar, and includes a first ring structure and a second ring structure. The first ring structure surrounds the second semiconductor pillar, and the second ring structure surrounds the third semiconductor pillar.

A semiconductor structure and a method for manufacturing the same are provided. The semiconductor structure includes a substrate, a gate structure and a dielectric layer. Herein, the substrate includes discrete semiconductor pillars. The semiconductor pillars are arranged at the top of the substrate and extend in a vertical direction. The substrate further includes a capacitor structure located at the top of the semiconductor pillar. The gate structure is arranged at the middle area of the semiconductor pillar and surrounds the semiconductor pillar. The dielectric layer is located between the gate structure and the semiconductor pillar, and covers the sidewall of the semiconductor pillar.

A method for forming a semiconductor structure comprises: providing a substrate, which includes a first area and a second area arranged in sequence in a second direction, the first area including active layers arranged at intervals in a third direction; forming an initial gate structure located on a surface of each active layer in the first area; etching the initial gate structures to form comb-shaped gate structures stacked in a third direction, each comb-shaped gate structure including first gate structures arranged at intervals in the first direction; and forming bit line structures extending in the third direction and capacitor structures extending in the second direction in the second area, the bit line structures and the capacitor structures are connecting to the first gate structures.

A semiconductor structure includes a plurality memory group provided in rows, each of the memory groups includes a plurality of memories arranged at intervals along a row direction, and for two adjacent ones of the memory groups, the memories in one memory group and the memories in another memory group are staggered.

A method for forming a semiconductor structure includes the following: a substrate is provided, the substrate including a first area and a second area arranged in sequence in a second direction and T-shaped active pillars located in the first area and the second area and arranged in an array in a first direction and a third direction, the first, second and third directions being perpendicular to one another, and the first and second directions being parallel to a surface of the substrate; T-shaped gate structures located on surfaces of the T-shaped active pillars and bit line structures extending in the third direction are formed in the first area, a plurality of T-shaped gate structures located in the first direction being interconnected; and capacitor structures extending in the second direction is formed in the second area, the bit line structures and the capacitor structures being connected to the T-shaped gate structures.

An embodiment provides a method for fabricating a semiconductor structure. The method includes: providing a semiconductor substrate having an active area, the active area including a first active area and a second active area isolated from each other; forming a bitline contact groove on the semiconductor substrate, the bitline contact groove exposing the first active area; forming an etch stop layer covering a sidewall of the bitline contact groove, the etch stop layer exposing a partial area of the first active area at a bottom of the bitline contact groove; etching the semiconductor substrate by using the etch stop layer as a mask to form a pit at the bottom of the bitline contact groove, the pit being at least partially positioned in the first active area; removing the etch stop layer; forming a bitline structure; and forming a conductive plug electrically connected to the second active area.

Apparatuses, devices and methods for fabricating one or more vertically integrated single bit capacitor-based memory cells is disclosed. A single bit capacitor-based memory cell can include a vertically oriented transistor and a vertically oriented capacitor that is vertically integrated with the transistor, so as to form a memory cell. Aspects of the disclosure include process steps for forming the transistor and the capacitor, including a first metal part of a capacitor, a second metal part of a capacitor and an electrically insulating layer disposed between the two. The transistor and the capacitor also include an electrical contact between them and a layer that insulates the transistor from the base layer or the underlying substrate.

The present disclosure provides a semiconductor structure and a manufacturing method thereof. The semiconductor structure includes: a base; a plurality of channel pillars perpendicularly provided on the base; a plurality of parallel bit lines, each of the bit lines wrapping lower parts of one column of the channel pillars; and a plurality of parallel word lines, each of the word lines wrapping upper parts of one row of the channel pillars, where the word lines and the bit lines are perpendicular to each other on a same projection plane; an insulating material layer is formed around the channel pillars below the bit lines, between adjacent bit lines, around the channel pillars between the bit lines and the word lines, and between adjacent word lines, separately; and gaps are formed in at least one of the insulating material layers.

A memory device includes a substrate, an active layer that is spaced apart from the substrate and laterally oriented, a word line that is laterally oriented in parallel to the active layer along one side of the active layer, an active body that is vertically oriented by penetrating through the active layer, a bit line that is vertically oriented by penetrating through the active layer to be spaced apart from one side of the active body, and a capacitor that is vertically oriented by penetrating through the active layer to be spaced apart from another side of the active body.