A semiconductor structure includes a substrate and a plurality of word lines located on a top surface of the substrate. Each of the word lines extends in a direction perpendicular to the top surface of the substrate. The plurality of word lines are arranged at intervals along a first direction. Any two adjacent ones of the word lines are arranged in an at least partially staggered manner along the first direction. The first direction is a direction parallel to the top surface of the substrate.

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.

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 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.

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.

A pseudo-triple-port memory is provided with read datapaths and write datapaths. The pseudo-triple-port memory includes a plurality of pseudo-triple-port bitcells, each pseudo-triple-port first bitcell having a first read port coupled to a first bit line, a second read port coupled to a second bit line, and a write port coupled to the first bit line and to the second bit line.

A semiconductor device and a related fabrication method are provided. The semiconductor device includes a conductive line on a substrate, a capping pattern that extends along an upper surface of the conductive line, a spacer structure that extends along a side surface of the conductive line and a side surface of the capping pattern, a buried contact electrically connected to the substrate, on a side surface of the spacer structure, a barrier conductive film extending along the buried contact and the spacer structure, and a landing pad electrically connected to the buried contact, on the barrier conductive film and the capping pattern, wherein an upper part of the spacer structure includes a spacer recess that is lower than or equal to an uppermost surface of the capping pattern, and the barrier conductive film extends along the spacer recess and does not cover the uppermost surface of the capping pattern.

A memory device that operates at high speed is provided. The memory device includes first and second memory cells, first and second bit lines, first and second switches, and a sense amplifier. The sense amplifier comprises a first node and a second node. The first memory cell is electrically connected to the first node through the first bit line and the first switch, and the second memory cell is electrically connected to the second node through the second bit line and the second switch. The sense amplifier amplifies the potential difference between the first node and the second node. The first memory cell and the second memory cell include an oxide semiconductor in a channel formation region.

A memory device includes a high density or 3D data memory and a 3D reference memory. The reference memory is used to generate a reference signal used to sense data in the data memory. Conversion circuitry converts signals from one memory cell or a group of memory cells in the reference memory into a reference signal. The reference signal is applied to a sense amplifier to sense data stored in a selected memory cell in the data memory.

In an embodiment, a device includes: a first word line over a substrate, the first word line including a first conductive material; a first bit line intersecting the first word line; a first memory film between the first bit line and the first word line; and a first conductive spacer between the first memory film and the first word line, the first conductive spacer including a second conductive material, the second conductive material having a different work function than the first conductive material, the first conductive material having a lower resistivity than the second conductive material.