DRAM circuitry comprises a memory array comprising memory cells individually comprising a transistor and a charge-storage device. The transistors individually comprise two source/drain regions having a gate there-between that is part of one of multiple wordlines of the memory array. One of the source/drain regions is electrically coupled to one of the charge-storage devices. The other of the source/drain regions is electrically coupled to one of multiple sense lines of the memory array. Peripheral circuitry comprises wordline-driver transistors having gates which individually comprise one of the wordlines and comprises sense-line-amplifier transistors having gates which individually comprise one of the sense lines. The sense-line-amplifier transistors and the wordline-driver transistors individually are a finFET having at least one fin comprising a channel region of the respective finFET. The sense-line-amplifier transistors and the wordline-driver transistors individually comprise two source/drain regions that individually comprise conductively-doped epitaxial semiconductor material that is adjacent one of two laterally-opposing sides of the at least one fin in a vertical cross-section. Methods are also disclosed.

A semiconductor structure and a method for manufacturing the same. The semiconductor structure includes a substrate, in which isolation trenches are formed, which are configured to divide a part of the substrate into multiple active areas extending in a first direction; first word line structures, each in the isolation trench between two adjacent ones of the active areas in the first direction, and a bottom of the first word line structure being positioned at a first-set-depth position of the substrate; and second word line structures, each located in an active area, and a bottom of the second word line structure being positioned at a second-set-depth position of the substrate. A first depth corresponding to the first-set-depth position is larger than or equal to a second depth corresponding to the second-set-depth position, and the difference between the first depth and the second depth is smaller than a preset value.

A method for manufacturing the semiconductor structure includes: a substrate is provided; isolation structures having a first depth are formed in the substrate; word line structures having a second depth are formed in the substrate, where part of the word line structures are formed in respective ones of the isolation structures, and the second depth is less than the first depth; the isolation structures are etched in a direction perpendicular to the substrate to form a first trench having a third depth in each isolation structure; and a first insulating layer covering the word line structures and the first trenches is formed on the substrate to form an air gap structure in each isolation structure.

A method of manufacturing a semiconductor structure includes: receiving a substrate having an active region and a non-active region adjacent to the active region; forming an etch stop layer over the non-active region of the substrate, in which the etch stop layer is oxide-free; forming an isolation over the etch stop layer; removing a portion of the active region and a portion of the isolation to form a first trench in the active region and a second trench over the etch stop layer, respectively, in which a thickness of the etch stop layer beneath the second trench is greater than a depth difference between the first trench and the second trench; forming a dielectric layer in the first trench; and filling a conductive material on the dielectric layer in the first trench and in the second trench. A semiconductor structure is also provided.

The present application provides a semiconductor device, which includes a shallow trench isolation structure, located in a substrate, and comprises a first region and a second region alternately arranged. The width of the first region is greater than the width of the second region. A first filling layer and a second filling layer are sequentially arranged in the first region, and a first filling layer is arranged in the second region; wherein, in the first region, the height of the first filling layer is lower than the height of the second filling layer. The device provides an advantage that the saddle-shaped shallow trench isolation structure in the first region reduces the trapping centers during any interference from adjacent word line structures, and also reduces the overlap areas of adjacent word line structures formed subsequently, thereby reducing parasitic capacitance, curtailing leakage and improving the semiconductor device's performance.

A manufacturing method for memory includes: providing a substrate, and forming a first isolation layer and discrete bit lines on the substrate; removing part of the first isolation layer by a thickness to form discrete first trenches; forming word lines filling the first trenches, wherein the word lines each has a first side wall and a second side wall opposite to each other; forming discrete through holes each being between adjacent word lines; forming a first dielectric layer on surface of exposed first side wall, and forming a second dielectric layer on surface of exposed second side wall; and forming an active layer filling the through holes.

A semiconductor device includes; an active region defined by an isolation film on a substrate, a word line in the substrate, the word line extending in a first direction and crossing the active region, a bit line above the word line and extending in a second direction, a contact between bit lines adjacent in the first direction, the contact connecting the active region and extending in a vertical direction, and a contact fence disposed on each of opposing side surfaces of the contact in the second direction and extending in the vertical direction, wherein the active region has a bar shape extending oblique to the first direction, and the contact fence includes a carbon-containing insulating film.

A semiconductor memory device includes a substrate, at least one word line, a plurality of bit lines and a plurality of insulating structures. The word line is disposed in the substrate, extends along a first direction, and includes a gate cap layer. The bit lines are disposed on the substrate and respectively extend along a second direction. The bit line crosses the word line, and includes a conductive layer. The insulating structures are disposed on the word line and respectively disposed between the bit lines. The bottom surface of the insulating structure is located in the gate cap layer. The area of the top surface of the insulating structure is larger than the area of the bottom surface of the insulating structure.

A semiconductor structure and a forming method thereof are provided. The method for forming a semiconductor structure includes providing a base including a semiconductor substrate and a well region located on a surface of the semiconductor substrate, in which the well region includes a plurality of active pillar columns arranged at intervals along a first direction, and each of the active pillar columns includes a plurality of active pillars arranged at intervals along a second direction, in which the first direction is perpendicular to the second direction; forming a plurality of bit line trenches by etching at least the well region and a partial thickness of the semiconductor substrate at bottoms of the active pillars; and forming buried bit lines in the bit line trenches.

A dynamic random access memory includes a substrate, an isolation structure, and a buried word line structure. The isolation structure is located in the substrate and defines multiple active regions. The buried word line structure is located in a word line trench in the substrate, and the word line trench passes through the active regions and the isolation structure. The buried word line structure includes a gate conductive layer, a first gate dielectric layer, and a second gate dielectric layer. The gate conductive layer is located in the word line trench. The first gate dielectric layer is located on a sidewall and a bottom surface of the word line trench. The second gate dielectric layer is located between the first gate dielectric layer and the gate conductive layer, and a top surface of the second gate dielectric layer is lower than a top surface of the gate conductive layer.