The present application provides a method for fabricating a semiconductor device including providing a substrate, concurrently forming a first conductive line and a bottom contact on the substrate, concurrently forming a first conductive line spacer on a sidewall of the first conductive line and a bottom contact spacer on a sidewall of the bottom contact, forming a first insulating layer over the substrate and concurrently forming an air gap between the first conductive line spacer and the bottom contact spacer.

A semiconductor device manufacturing method according to the exemplary embodiments of the disclosure includes patterning a substrate, thereby forming an active pattern, forming a trench penetrating the active pattern, forming a support layer covering the trench, forming a first opening at the support layer, forming a gate electrode layer filling the trench through the first opening, and forming a bit line structure electrically connected to the active pattern. The support layer includes a base portion covering a top surface of the active pattern, and a support disposed in the trench.

A semiconductor structure includes a semiconductor substrate including a first active region and a chop region. The semiconductor structure also includes a source/drain region disposed in the first active region, an isolation structure disposed in the chop region, and a gate structure extending at least across the isolation structure in the chop region. The gate structure includes a gate electrode layer and a gate lining layer lining on the gate electrode layer. The gate lining layer includes a first portion having an upper surface that is lower than a bottom surface of the source/drain region.

A memory includes a plurality of semiconductor structures stacked onto one another. Each of the plurality of semiconductor structures include: a first base including a peripheral circuit structure; a first integrated circuit layer disposed on the first base and electrically connected to the peripheral circuit structure; and a second base disposed on the first integrated circuit layer. A first dielectric layer is disposed between the first integrated circuit layer and the second base. The second base includes a storage circuit structure. Each of the first base and the second base includes a semiconductor layer.

A semiconductor device may include a word line stack over a substrate; a plurality of supporters including vertically extending blocking spacers to support the word line stack; and storage nodes of a capacitor disposed laterally between the supporters.

Memory devices and methods of forming memory devices are described. The memory devices comprise two work-function metal layers, where one work-function layer has a lower work-function than the other work-function layer. The low work-function layer may reduce gate-induced drain leakage current losses. Methods of forming memory devices are also described.

A semiconductor device includes a substrate, a passing word line in the substrate, and a dielectric structure surrounding the passing word line. The dielectric structure has an enlargement portion at a bottom of the dielectric structure, and a maximum width of the enlargement portion of the dielectric structure is wider than a width of a top of the dielectric structure.

A manufacturing method of a semiconductor device includes forming an opening in a substrate, implanting a dopant in the substrate from a sidewall of the opening such that a doping region is formed in the substrate at the sidewall of the opening, filling a dielectric material in the opening to form a first dielectric structure after implanting the dopant in the substrate from the sidewall of the opening, and forming a passing word line in the dielectric structure.

Embodiments of the present disclosure relate to a semiconductor structure and a manufacturing method thereof, a data storage device and a data read-write device. The semiconductor structure includes: a substrate, a plurality of active regions separated from each other being formed in the substrate; a trench, located in the active region; a first gate structure, located in the trench, and configured to be applied with a first applied voltage; a second gate structure, located in the trench, and located above the first gate structure, and configured to be applied with a second applied voltage, the second applied voltage being greater than the first applied voltage; and an insulating isolation layer, located in the trench, and located between the first gate structure and the second gate structure.

A method for forming a semiconductor memory structure includes providing a semiconductor substrate; forming a hard mask layer on the semiconductor substrate; forming a contact opening corresponding to the pair of word lines through the hard mask layer and a portion of the semiconductor substrate; forming a pair of spacers on sidewalls of the contact opening; filling the contact opening with a conductive material to form a contact; forming a bit line directly above the contact and the pair of spacers, and forming a dielectric liner on sidewalls of the bit line. The pair of word lines is embedded in an active region of the semiconductor substrate and extends in a first direction. The bit line extends in a second direction. The first direction is perpendicular to the second direction.