An integrated circuit device includes a device isolation trench defining an active area, a gate trench extending in a first direction across the active area and the device isolation film, a gate dielectric film covering an inner wall of the gate trench, and a conductive line filling a part of the gate trench above the gate dielectric film. The active area includes a fin body portion located under the conductive line, and a thinner fin portion protruding from the fin body portion toward the conductive line and having a width less than a width of the fin body portion in the first direction.

An example apparatus includes a first source/drain region and a second source/drain region formed in a substrate. The first source/drain region and the second source/drain region are separated by a channel. The apparatus includes a gate opposing the channel. The gate includes noble metal nanoparticles. A sense line is coupled to the first source/drain region and a storage node is coupled to the second source/drain region.

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.

Provided are a semiconductor structure and a method for forming same. The method includes the following operations. Active areas and first isolation structures disposed at intervals are provided. Second isolation structures located between adjacent active areas are provided, and top surfaces of the second isolation structures are higher than or flush with top surfaces of the active areas. A mask layer are formed, pattern openings of which expose part of the top surfaces of the active areas, and the second isolation structures are located at two opposite sides of part of the active areas. The part of the active areas exposed by the pattern openings and part of the first isolation structures are etched to form intermediate grooves at least exposing part of surfaces of the active areas. Bit line structures are formed, which are electrically connected to top surfaces exposed by the intermediate grooves.

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.

Present invention relates to a semiconductor device including a buried gate structure. A semiconductor device comprises a substrate; a first fluorine-containing layer over the substrate; a trench formed in the first fluorine-containing layer and extended into the substrate; a gate dielectric layer formed over the trench; a gate electrode formed over the gate dielectric layer and filling a portion of the trench; a second fluorine-containing layer formed over the gate electrode; and a fluorine-containing passivation layer between the gate dielectric layer and the gate electrode.

A semiconductor device includes a bit line structure and a storage contact spaced apart from each other over a substrate; a bit line spacer formed on a sidewall of the bit line structure; a landing pad formed over the storage contact; a boron-containing capping layer disposed between the bit line structure and the landing pad; a boron-containing etch stop layer over the boron-containing capping layer; and a capacitor including a storage node coupled to the landing pad by passing through the boron-containing etch stop layer.

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.

A semiconductor device includes a device isolation layer defining first and second active regions, a buried contact connected to the second active region, and first and second bit line structures disposed on the first and second active regions. Each of the first and second bit line structures comprises a bit line contact part and a bit line pass part. The bit line contact part is electrically connected to the first active region. The bit line pass part is disposed on the device isolation layer. A height of a lowest part of the buried contact is smaller than a height of a lowest part of the bit line pass part. The height of the lowest part of the buried contact is greater than a height of a lowest part of the bit line contact part. A lower end of the bit line pass part is buried in the second active region.

A semiconductor device may include active patterns extended in a first direction and spaced apart from each other in the first direction, a device isolation layer defining the active patterns, an insulating structure provided between the active patterns and between the device isolation layer, and a gate structure disposed on the insulating structure and extended in a second direction crossing the first direction. The gate structure may include an upper portion and a lower portion. The lower portion of the gate structure may be enclosed by the insulating structure.