The present disclosure provides a method of manufacturing a semiconductor structure, and a semiconductor structure, relating to the technical field of semiconductors. The method of manufacturing a semiconductor structure includes: providing a substrate; forming multiple initial active pillars on the substrate; forming a gate layer between initial active pillars; and forming a first dielectric layer with openings on the gate layer and on the initial active pillars; removing part of the initial active pillar located in each opening to form an active pillar; and removing part of the gate layer to form an isolation trench and a word line, such that two adjacent active pillars in the same row are located on two sides of the isolation trench.

A gate structure may include a first gate electrode extending in a first direction, a second gate electrode on a portion of the first gate electrode, a gate mask on the first and second gate electrodes, and a gate insulation pattern on a lower surface and a sidewall of the first gate electrode and sidewalls of the second gate electrode and the gate mask. The gate structure is in an upper portion of a substrate. A grain size of the second gate electrode is greater than a grain size of the first gate electrode.

A method used in forming memory circuitry comprises forming transistors individually comprising one source/drain region and another source/drain region. A channel region is between the one and the another source/drain regions. A conductive gate is operatively proximate the channel region. Conductive vias are formed that are individually directly electrically coupled to the another source/drain region. Conductor material is formed that is directly coupled to the one source/drain region. The conductor material is patterned in one direction to form horizontal lines of the conductor material that have a horizontal trench between immediately-adjacent of the horizontal conductor-material lines. In a self-aligned manner, digitlines are formed that are individually in individual of the trenches between the immediately-adjacent conductor-material lines. After forming the digitlines, the conductor material is patterned in another direction that is horizontally angled from the one direction to form conductor vias that are individually directly electrically coupled to the one source/drain region. A plurality of storage elements is formed that are individually directly electrically coupled to individual of the conductor vias. Other aspects, including structure independent of method, are disclosed.

A method of fabricating a memory device includes forming an oxide layer on a semiconductor substrate, and forming an isolation structure in the semiconductor substrate and the oxide layer to define an active area. The method also includes forming a word line and a bit line in the semiconductor substrate, wherein the bit line is above the word line. The method further includes removing the oxide layer to form a recess between the isolation structure and the bit line, and forming a storage node contact in the recess. In addition, from a top view, the storage node contact of the memory device overlaps a corresponding portion of the active area.

Embodiments of the present disclosure provide a semiconductor structure and a manufacturing method thereof. According to embodiments of the present disclosure, a height of the work function layer, especially a height of the second portion of the work function layer, is significantly increased, and a height of the first gate material layer is significantly reduced, so that the height ratio of the second portion of the work function layer to the first gate material layer to the second gate material layer is maintained at 3 to 8:1 to 1.5:1; therefore, it can be ensured that the work function of the WL groove filling material layer of the recessed gate structure with a small WL width will be significantly increased, thereby greatly weakening the row hammer effect at the bottom of the WL groove and obviously reducing the GIDL effect at the upper part of the WL groove.

A method for fabricating a semiconductor device includes: forming a first conductive structure over a substrate; forming a multi-layer spacer including a non-conformal sacrificial spacer on both sidewalls of the first conductive structure; forming a second conductive structure adjacent to the first conductive structure with the multi-layer spacer therebetween; forming an air gap by removing the non-conformal sacrificial spacer; forming a capping layer covering the second conductive structure and the air gap; forming an opening that exposes a top surface of the second conductive structure by etching the capping layer; and forming a conductive pad coupled to the second conductive structure in the opening.

The present invention relates to the field of semiconductor manufacturing technologies, in particular to a semiconductor device and a method of forming the same. The method of forming the semiconductor device includes the following steps: forming a substrate with a trench, a gate dielectric layer covering an inner wall of the trench, a barrier layer covering a portion of a surface of the gate dielectric layer, and a first gate layer filled on an surface of the barrier layer being disposed in the trench; removing a portion of the barrier layer to form an groove located between the first gate layer and the gate dielectric layer; forming a channel dielectric layer at least covering an inner wall of the groove and a top surface of the first gate layer; and forming a second gate layer at least partially filling an interior of the groove.

A semiconductor device includes a substrate including a cell area and an interface area surrounding the cell area, the substrate including a device isolation layer defining an active region in the cell area and including an area isolation layer in the interface area, a gate structure extending in the cell area in a first horizontal direction, the gate structure being buried in the substrate and intersecting the active region, a bit line structure intersecting the gate structure and extending in a second horizontal direction intersecting the first horizontal direction, and dummy gate structures extending in the interface area in the first horizontal direction and being spaced apart from one another in the second horizontal direction. The dummy gate structures are buried in the area isolation layer and being spaced apart from the gate structure in the second horizontal direction.

Provided is a semiconductor memory device comprising a device isolation pattern in a substrate and defining first and second active sections spaced apart from each other, wherein a center of the first active section is adjacent to an end of the second active section, a bit line that crosses over the center of the first active section, a bit-line contact between the bit line and the first active section, and a first storage node pad on the end of the second active section. The first storage node pad includes a first pad sidewall and a second pad sidewall. The first pad sidewall is adjacent to the bit-line contact. The second pad sidewall is opposite to the first pad sidewall. When viewed in plan, the second pad sidewall is convex in a direction away from the bit-line contact.

A semiconductor device includes: a substrate; a memory cell region over the substrate; a peripheral region over the substrate, the peripheral region being adjacent to the memory cell region; and a plurality of first and second word-lines extending across the memory cell region and the peripheral region; wherein the plurality of first word-lines and the plurality of second word-lines are arranged alternately with each other; and wherein the length of the first word-line in the peripheral region is longer than the length of the second word-line in the peripheral region.