A semiconductor device may include a substrate including a cell region and a peripheral region, a gate stack on the peripheral region, an interlayer insulating layer on the gate stack, peripheral circuit interconnection lines on the interlayer insulating layer, and an interconnection insulating pattern between the peripheral circuit interconnection lines. The interconnection insulating pattern may include a pair of vertical portions spaced apart from each other in a first direction parallel to a top surface of the substrate and a connecting portion connecting the vertical portions to each other. Each of the vertical portions of the interconnection insulating pattern may have a first thickness at a same level as top surfaces of the peripheral circuit interconnection lines and a second thickness at a same level as bottom surfaces of the peripheral circuit interconnection lines. The first thickness may be substantially equal to the second thickness.

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.

A semiconductor device may include a substrate including a cell region, a peripheral region, and a boundary region between the cell region and the peripheral region, bit lines provided on the cell region and extended in a first direction parallel to a top surface of the substrate, bit line capping patterns provided on the bit lines, and a boundary pattern provided on the boundary region. End portions of the bit lines may be in contact with a first interface of the boundary pattern, and the bit line capping patterns may include the same material as the boundary pattern.

Apparatuses and methods for manufacturing semiconductor memory devices are described. An example method includes: forming a plurality of capacitor contacts on a substrate; forming a dielectric layer on the plurality of capacitor contacts; removing portions of the dielectric layer to form a plurality of openings in the dielectric layer; exposing the plurality of capacitor contacts at bottoms of the plurality of the corresponding openings; and depositing conductive material to form a plurality of interconnects in the plurality of corresponding openings.

A semiconductor device includes; cell transistors on a substrate, lower electrodes respectively connected to the cell transistors, arranged according to a first pitch in a first horizontal direction, and extending in a vertical direction, and an etching stop layer surrounding lower sidewalls of the lower electrodes and arranged at a level higher than a level of the cell transistors, wherein the etching stop layer includes a first portion vertically overlapping the lower electrodes and a second portion laterally surrounding the first portion, and the second portion includes recesses arranged according to a second pitch in the first horizontal direction.

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 invention discloses a semiconductor memory device, which is characterized by comprising a substrate defining a cell region and an adjacent periphery region, a plurality of bit lines are arranged on the substrate and arranged along a first direction, each bit line comprises a conductive part, and the bit line comprises four sidewalls, and a spacer surrounds the four sidewalls of the bit line, the spacer comprises two short spacers covering two ends of the conductive part, two long spacers covering the two long sides of the conductive part, and a plurality of storage node contact isolations located between any two adjacent bit lines, at least a part of the storage node contact isolations cover directly above the spacers. The structure of the invention can improve the electrical isolation effect, preferably avoid leakage current and improve the quality of components.

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.

Disclosed herein is a method that includes epitaxially growing SiGe layer on a silicon substrate, etching the SiGe layer and the silicon substrate to form an active region covered with the SiGe layer, first etching the SiGe layer formed on a first region of the active region without etching the SiGe layer formed on a second region of the active region to form a first trench, and second etching the SiGe layer remaining on an inner wall of the first trench.

Embodiments disclose a buried bit line structure, a method for fabricating the buried bit line structure, and a memory. The buried bit line structure includes: a substrate having a bit line trench; a bit line metal filled in the bit line trench; and a bit line contact filled in the bit line trench and positioned on the bit line metal, where an arc-shaped contact surface is provided between the bit line contact and the bit line metal. By setting a contact surface between the bit line contact and the bit line metal to be the arc-shaped contact surface, a contact area between the bit line contact and the bit line metal is increased, electrical conductivity of the bit line structure is enhanced.