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.

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 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.

Ferroelectric memory and methods of forming the same are provided. An example memory cell can include a buried recessed access device (BRAD) formed in a substrate and a ferroelectric capacitor formed on the BRAD.

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.

A semiconductor structure includes a substrate and a buried gate structure in the substrate. The buried gate structure includes a gate dielectric layer, a first work function layer, a barrier layer, and a second work function layer. The gate dielectric layer is formed on the sidewalls and the bottom surface of a trench. The work function layer is formed in the trench and contacts the sidewalls and the bottom surface of the gate dielectric layer. The barrier layer is formed on the top surface of the first work function layer. The second work function layer is formed on the barrier layer, and the sidewall of the second work function layer is separated from the gate dielectric layer by a distance. The semiconductor structure further includes an insulating layer in the trench and on the second work function layer.

A semiconductor memory device includes a substrate including a cell area and a peripheral area, a plurality of capacitors including a plurality of lower electrodes arranged in the cell area, a plurality of capacitor dielectric layers covering the plurality of lower electrodes, and an upper electrode on the plurality of capacitor dielectric layers, an etch stop layer covering the upper electrode, a filling insulation layer covering the etch stop layer and arranged in the cell area and the peripheral area, a plurality of wiring lines on the filling insulation layer, and a first wiring contact plug electrically connecting at least one of the plurality of wiring lines to the upper electrode. The upper electrode includes a first upper electrode layer covering the plurality of capacitor dielectric layers and including a semiconductor material and a second upper electrode layer covering the first upper electrode layer and including a metallic material.

An IC package includes a substrate, a first monolithic die, a second monolithic die and a third monolithic die. A processing unit circuit is formed in the first monolithic die. A plurality of SRAM arrays are formed in the second monolithic die, wherein the plurality of SRAM arrays include at least 5-20 G Bytes. A plurality of DRAM arrays are formed in the third monolithic die, wherein the plurality of DRAM arrays include at least 64-512 G Bytes. The first monolithic die, the second monolithic die and the third monolithic die are vertically stacked above the substrate. The third monolithic die is electrically connected to the first monolithic die through the second monolithic die.