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 memory integrated circuit is provided. The memory integrated circuit includes a first memory array, a second memory array and a driving circuit. The first and second memory arrays are laterally spaced apart, and respectively include: memory cells, each including an access transistor and a storage capacitor coupled to the access transistor; bit lines, respectively coupled to a row of the memory cells; and word lines, respectively coupled to a column of the memory cells. The driving circuit is disposed below the first and second memory arrays, and includes sense amplifiers. Each of the bit lines in the first memory array and one of the bit lines in the second memory array are routed to input lines of one of the sense amplifiers.

Disclosed are semiconductor devices and their fabrication methods. The semiconductor device comprises a substrate including a peripheral block and cell blocks each including a cell center region, a cell edge region, and a cell middle region, and bit lines extending on each cell block in a first direction. The bit lines include center bit lines, middle bit lines, and edge bit lines. The bit line has first and second lateral surfaces opposite to each other in a second direction. The first lateral surface straightly extends along the first direction on the cell center region, the cell middle region, and the cell edge region. The second lateral surface straightly extends along the first direction on the cell center region and the cell edge region, and the second lateral surface extends along a third direction, that intersects the first direction and the second direction, on the cell middle region.

The present application discloses a method for fabricating a semiconductor device. The method includes: providing a substrate including a plurality of first regions and second regions; forming a plurality of bit line contacts over the first regions of the substrate; forming a plurality of bit lines respectively over the plurality of bit line contacts; forming a plurality of capacitor contacts respectively over the second regions of the substrate; forming a plurality of capacitor plugs respectively over the plurality of capacitor contacts; forming a plurality of first spacers respectively over a plurality of protruding portions of the plurality of capacitor plugs, wherein a width of the first spacer is larger than a width of the capacitor plug; and forming a plurality of capacitor structures over the plurality of first spacers; wherein at least one of the plurality of bit lines is an undulating stripe extending between two adjacent capacitor contacts.

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.

In a method of manufacturing a semiconductor memory device, a plurality of first conductive structures including a first conductive pattern and a hard mask are sequentially stacked on a substrate. A plurality of preliminary spacer structures including first spacers, sacrificial spacers and second spacers are sequentially stacked on sidewalls of the conductive structures. A plurality of pad structures are formed on the substrate between the preliminary spacer structures, and define openings exposing an upper portion of the sacrificial spacers. A first mask pattern is formed to cover surfaces of the pad structures, and expose the upper portion of the sacrificial spacers. The sacrificial spacers are removed to form first spacer structures having respective air spacers, and the first spacer structures include the first spacers, the air spacers and the second spacers sequentially stacked on the sidewalls of the conductive structures.

Semiconductor device may include a landing pad and a lower electrode that is on and is connected to the landing pad and includes an outer portion and an inner portion inside the outer portion. The outer portion includes first and second regions. The semiconductor devices may also include a dielectric film on the first region of the outer portion on the lower electrode and an upper electrode on the dielectric film. The first region of the outer portion of the lower electrode may include a silicon (Si) dopant, the dielectric film does not extend along the second region of the outer portion. A concentration of the silicon dopant in the first region of the outer portion is different from a concentration of the silicon dopant in the second region of the outer portion and is higher than a concentration of the silicon dopant in the inner portion.

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.

Embodiments provide an integrated capacitor disposed directly over and aligned to a vertical gate all around memory cell transistor. In some embodiments, an air gap may be provided between adjacent word lines to provide a low k dielectric effect between word lines. In some embodiments, a bottom bitline structure may be split across multiple layers. In some embodiments, a second tier of vertical cells may be positioned over a first tier of vertical cells.