Some embodiments include an integrated assembly having digit lines which extend along a first direction, and which are spaced from one another by intervening regions. Each of the intervening regions has a first width along a cross-section. Pillars extend upwardly from the digit lines; and the pillars include transistor channel regions extending vertically between upper and lower source/drain regions. Storage elements are coupled with the upper source/drain regions. Wordlines extend along a second direction which crosses the first direction. The wordlines include gate regions adjacent the channel regions. Shield lines are within the intervening regions and extend along the first direction. The shield lines may be coupled with at least one reference voltage node. Some embodiments include methods of forming integrated assemblies.

Disclosed is a method for manufacturing a contact hole, a semiconductor structure and electronic equipment. The method includes: forming a mask layer on an upper end face of a first oxide layer of the semiconductor structure, and exposing a pattern of a target contact hole on the mask layer; exposing a portion, corresponding to a target contact hole, of an upper end face of a contact layer and a portion, corresponding to the target contact hole, of an upper end face of an upper layer structure; depositing a second insulation layer on an etched surface, and depositing a second oxide layer on the second insulation layer; and removing portions, above the upper end face of the first oxide layer, of the second insulation layer and the second oxide layer, and removing a part of the contact layer, and exposing an upper end face of a zeroth layer contact.

The disclosure relates to a semiconductor storage device and a forming method thereof. The semiconductor storage device includes a substrate; a plurality of active region structures provided on the substrate; a shallow trench isolation structure provided within the substrate, the shallow trench isolation structure surround the plurality of active region structures; a plurality of conductive line structures, extending parallel to each other along a first direction, the conductive line structure include a first region and a second region, the first region being located over each of the plurality of active region structures, the second region is located over the shallow trench isolation structure; in a direction perpendicular to the substrate, the depth of the first region is greater than the depth of the second region.

A method used in forming an array of memory cells comprises forming lines of top-source/drain-region material, bottom-source/drain-region material, and channel-region material vertically there-between in rows in a first direction. The lines are spaced from one another in a second direction. The top-source/drain-region material, bottom-source/drain-region material, and channel-region material have respective opposing sides. The channel-region material on its opposing sides is laterally recessed in the second direction relative to the top-source/drain-region material and the bottom-source/drain-region material on their opposing sides to form a pair of lateral recesses in the opposing sides of the channel-region material in individual of the rows. After the pair of lateral recesses are formed, the lines of the top-source/drain-region material, the channel-region material, and the bottom-source/drain-region material are patterned in the second direction to comprise pillars of individual transistors. Rows of wordlines are formed in the first direction that individually are operatively aside the channel-region material of individual of the pillars in the pairs of lateral recesses and that interconnect the transistors in that individual row. Other embodiments, including structure independent of method, are disclosed.

The present disclosure provides a method of manufacturing a semiconductor structure and a semiconductor structure, and relates to the technical field of semiconductors. The method of manufacturing a semiconductor structure includes: providing a base; forming a functional stack on the base, wherein the functional stack includes a first doped layer, a second doped layer and a third doped layer that are stacked sequentially, the first doped layer is provided on the base, dopant ions in the second doped layer are different from dopant ions in the first doped layer, and the dopant ions in the first doped layer are the same as dopant ions in the third doped layer; and removing a part of the functional stack to form a plurality of active pillars arranged at intervals.

A P layer 2 having a band shape is on an insulating substrate 1. An N.sup.+ layer 3a connected to a first source line SL1 and an N.sup.+ layer 3b connected to a first bit line are on respective sides of the P layer 2 in a first direction parallel to the insulating substrate. A first gate insulating layer 4a surrounds a portion of the P layer 2 connected to the N.sup.+ layer 3a, and a second gate insulating layer 4b surrounds the P layer 2 connected to the N.sup.+ layer 3b. A first gate conductor layer 5a connected to a first plate line and a second gate conductor layer 5b connected to a second plate line are isolated from each other and cover two respective side surfaces of the first gate insulating layer 4a in a second direction perpendicular to the first direction. A third gate conductor layer 5c connected to a first word line surrounds the second gate insulating layer 4b. These components constitute a dynamic flash memory.

A semiconductor structure includes a substrate with a plurality of word line trenches and source/drain regions each adjacent to each word line trench; a word line located in the word line trench, which includes a first conductive layer located at a bottom of the word line trench, a single junction layer and a second conductive layer stacked in sequence, in which a projection of the word line on a sidewall of the word line trench and the projection of the source/drain region on the sidewall of the word line trench have an overlapping region with a preset height, and when a voltage applied to the word line is less than a preset voltage, a resistance of the single junction layer is greater than the preset resistance, to make the first conductive layer and the second conductive layer disconnected.

Described herein are methods of filling features with tungsten, and related systems and apparatus, involving inhibition of tungsten nucleation. In some embodiments, the methods involve selective inhibition along a feature profile. Methods of selectively inhibiting tungsten nucleation can include exposing the feature to a direct or remote plasma. In certain embodiments, the substrate can be biased during selective inhibition. Process parameters including bias power, exposure time, plasma power, process pressure and plasma chemistry can be used to tune the inhibition profile. The methods described herein can be used to fill vertical features, such as in tungsten vias, and horizontal features, such as vertical NAND (VNAND) wordlines. The methods may be used for both conformal fill and bottom-up/inside-out fill. Examples of applications include logic and memory contact fill, DRAM buried wordline fill, vertically integrated memory gate/wordline fill, and 3-D integration using through-silicon vias.

Embodiments provide an integrated capacitor disposed directly over and aligned to a vertical gate all around memory cell transistor. In some embodiments, an air gap may be provided between adjacent word lines to provide a low k dielectric effect between word lines. In some embodiments, a bottom bitline structure may be split across multiple layers. In some embodiments, a second tier of vertical cells may be positioned over a first tier of vertical cells.

A DRAM integrated circuit device is described in which at least some of the peripheral circuits associated with the memory arrays are provided on a first substrate. The memory arrays are provided on a second substrate stacked on the first substrate, thus forming a DRAM integrated circuit device on a stacked-substrate assembly. Vias that electrically connect the memory arrays on the second substrate to the peripheral circuits on the first substrate are fabricated using high aspect ratio via fabrication techniques.