A method of depositing nitride films is disclosed. Some embodiments of the disclosure provide a PEALD process for depositing nitride films which utilizes separate reaction and nitridation plasmas. In some embodiments, the nitride films have improved growth per cycle (GPC) relative to films deposited by thermal processes or plasma processes with only a single plasma exposure. In some embodiments, the nitride films have improved film quality relative to films deposited by thermal processes or plasma processes with only a single plasma exposure.

Provided is a batch-type substrate processing apparatus. The substrate processing apparatus includes a vertical reaction tube having an internal space for receiving a substrate boat in which a substrate is stacked in multiple stages, a deposition gas supply unit configured to supply a deposition gas inside the reaction tube, a heater disposed outside the reaction tube to provide a thermal energy inside the reaction tube, and an adhesion layer coated on an inner wall of the reaction tube and to which a deposition by-product layer by an excess deposition gas is attached.

Disclosed are methods and systems for depositing layers comprising a transition metal and a group 13 element. The layers are formed onto a surface of a substrate. The deposition process may be a cyclical deposition process. Exemplary structures in which the layers may be incorporated include field effect transistors, VNAND cells, metal-insulator-metal (MIM) structures, and DRAM capacitors.

Processing methods may be performed to form a fan-out interconnect structure. The methods may include forming a semiconductor active device structure overlying a first substrate. The semiconductor active device structure may include first conductive contacts. The methods may include forming an interconnect structure overlying a second substrate. The interconnect structure may include second conductive contacts. The methods may also include joining the first substrate with the second substrate. The joining may include coupling the first conductive contacts with the second conductive contacts. The interconnect structure may extend beyond the lateral dimensions of the semiconductor active device structure.

The present disclosure describes an exemplary method that can prevent or reduce out-diffusion of Cu from interconnect layers to magnetic tunnel junction (MTJ) structures. The method includes forming an interconnect layer over a substrate that includes an interlayer dielectric stack with openings therein; disposing a metal in the openings to form corresponding conductive structures; and selectively depositing a diffusion barrier layer on the metal. In the method, selectively depositing the diffusion barrier layer includes pre-treating the surface of the metal; disposing a precursor to selectively form a partially-decomposed precursor layer on the metal; and exposing the partially-decomposed precursor layer to a plasma to form the diffusion barrier layer. The method further includes forming an MTJ structure on the interconnect layer over the diffusion barrier layer, where the bottom electrode of the MTJ structure is aligned to the diffusion barrier layer.

Provided are an interconnect structure and an electronic device including the same. The interconnect structure may include a conductive wiring having a certain pattern, a dielectric layer on side surfaces of the conductive wiring, a capping layer on the conductive wiring, and a graphene layer on the dielectric layer. The graphene layer may include a graphene material. A ratio of carbons having sp.sup.3 bonds to carbons having sp.sup.2 bonds in the graphene material is 1 or less.

A method includes forming a buffer dielectric layer over a carrier, and forming a first dielectric layer and a first redistribution line over the buffer dielectric layer. The first redistribution line is in the first dielectric layer. The method further includes performing a planarization on the first dielectric layer to level a top surface of the first dielectric layer, forming a metal post over and electrically coupling to the first redistribution line, and encapsulating the metal post in an encapsulating material. The encapsulating material contacts a top surface of the planarized top surface of the first dielectric layer.

A semiconductor device includes a substrate, a first interlayer insulating layer on the substrate, a lower wiring pattern inside the first interlayer insulating layer, an etch stop layer on the first interlayer insulating layer, a second interlayer insulating layer on the etch stop layer, a via trench inside the second interlayer insulating layer and the etch stop layer and that extends to the lower wiring pattern, a via inside the via trench and that is in contact with the second interlayer insulating layer and is formed of a single film, an upper wiring trench formed inside the second interlayer insulating layer on the via, and an upper wiring pattern inside the upper wiring trench and that includes an upper wiring barrier layer and an upper wiring filling layer on the upper wiring barrier layer An upper surface of the via is in contact with the upper wiring filling layer.

There is provided a semiconductor device including an etching stop film which is placed disposed on a substrate; an interlayer insulating film which is disposed on the etching stop film; a trench which penetrates the interlayer insulating film and the etching stop film; a spacer which extends along side walls of the trench; a barrier film which extends along the spacer and a bottom surface of the trench; and a filling film which fills the trench on the barrier film. The trench includes a first trench and a second trench which are spaced apart from each other in a first direction and have different widths from each other in the first direction. A bottom surface of the second trench is placed disposed below a bottom surface of the first trench.

A semiconductor structure and a method for fabricating a semiconductor structure are provided. In the semiconductor structure, a side of a film layer structure facing away from a substrate is provided with a wiring layer, a side of the substrate facing away from the film layer structure is provided with a connecting hole extending to the wiring layer, and an insulating layer is arranged on a hole wall of the connecting hole. A barrier ring is arranged on the insulating layer, a center line of the barrier ring is arranged collinearly with a center line of the connecting hole, and diffusibility of the barrier ring is less than diffusibility of the wiring layer. A connecting post joined to the wiring layer is arranged in the connecting hole.