In an embodiment, a semiconductor device includes a semiconductor substrate, a LDMOS transistor arranged in a front surface of the semiconductor substrate and a conductive through substrate via. The conductive through substrate via includes a via extending from the front surface to a rear surface of the semiconductor substrate, a conductive plug filling a first portion of the via and a conductive liner layer lining side walls of a second portion of the via and electrically coupled to the conductive plug.

A process of forming a semiconductor device that includes an interconnection formed by electro-plating is disclosed. The process comprises steps of: forming a stopper layer on the first insulating film; covering the stopper layer and the first insulating film with a second insulating film; preparing a first mask having an edge that overlaps with the stopper layer; depositing a seed layer on the first mask and the second insulating film that is exposed from the first mask; preparing a second mask having an edge that overlaps with the stopper layer, the edge of the first mask retreating from the edge of the second mask; forming an upper layer on the seed layer by electro-plating a metal so as not to overlap with the first mask; and removing the seed layer exposed from the upper layer by etching.

A three dimensional multi-die package includes a first die and second die. The first die includes a contact attached to solder. The second die is thinned by adhesively attaching a handler to a top side of the second die and thinning a bottom side of the second die. The second die includes a multilayer contact of layered metallurgy that inhibits transfer of adhesive thereto. The layered metallurgy includes at least one layer that is wettable to the solder. The multilayer contact may include a Nickel layer, a Copper layer upon the Nickel layer, and a Nickel-Iron layer upon the Copper layer. The multilayer contact may also include a Nickel layer, a Copper-Tin layer upon the Nickel layer, and a Tin layer upon the Copper-Tin layer.

A method of forming a titanium nitride (TiN) diffusion barrier includes exposing a deposition surface to a first pulse of a titanium-containing precursor and to a first pulse of a nitrogen-rich plasma to form a first TiN layer with a first nitrogen concentration making a lower portion of the TiN diffusion barrier, the first nitrogen concentration of the first TiN layer is increased by the first pulse of the nitrogen-rich plasma reducing a reactivity of the lower portion of the TiN diffusion barrier to prevent fluorine diffusion. The first TiN layer is exposed to second pulses of the titanium-containing precursor and the nitrogen-rich plasma to form a second TiN layer with a second nitrogen concentration above the first TiN layer making an upper portion of the TiN diffusion barrier, the first pulse of the nitrogen-rich plasma has a substantially longer duration than the second pulse of the nitrogen-rich plasma.

A semiconductor device includes a semiconductor substrate, a dielectric structure, an electrical insulating and thermal conductive layer and a circuit layer. The electrical insulating and thermal conductive layer is disposed over the semiconductor substrate. The dielectric structure is disposed over the electrical insulating and thermal conductive layer, wherein a thermal conductivity of the electrical insulating and thermal conductive layer is substantially greater than a thermal conductivity of the dielectric structure. The circuit layer is disposed in the dielectric structure.

The semiconductor memory device includes a stack structure including first material films stacked, but spaced apart from each other, in a slimming region, the first material films being stacked in a step structure in the slimming region, a contact hole exposing a portion of the first material films formed in different layers in the slimming region, and a plurality of material films that are applied and etched to electrically connect one of the material layers to a peripheral circuit.

A method for manufacturing an array substrate comprises forming a pattern including an active layer, a gate insulating layer and a gate on a base substrate, and forming a pattern including an interlayer dielectric layer, a source, a drain and a pixel electrode through a single patterning process on the base substrate formed with the pattern of the active layer, the gate insulating layer and the gate. An array substrate and a display device are further provided.

For simplifying the dual-damascene formation steps of a multilevel Cu interconnect, a formation step of an antireflective film below a photoresist film is omitted. Described specifically, an interlayer insulating film is dry etched with a photoresist film formed thereover as a mask, and interconnect trenches are formed by terminating etching at the surface of a stopper film formed in the interlayer insulating film. The stopper film is made of an SiCN film having a low optical reflectance, thereby causing it to serve as an antireflective film when the photoresist film is exposed.

A plating method can improve adhesivity with a substrate. The plating method of performing a plating process on the substrate includes forming a vacuum-deposited layer 2A on the substrate 2 by performing a vacuum deposition process on the substrate 2; forming an adhesion layer 21 and a catalyst adsorption layer 22 on the vacuum-deposited layer 2A of the substrate 2; and forming a plating layer stacked body 23 having a first plating layer 23a and a second plating layer 23b which function as a barrier film on the catalyst adsorption layer 22 of the substrate 2. By forming the vacuum-deposited layer 2A, a surface of the substrate 2 can be smoothened, so that the vacuum-deposited layer 2A serving as an underlying layer can improve the adhesivity.

A method of manufacturing a semiconductor device may include: forming an opening in a dielectric layer, the opening exposing a non-conductive layer disposed over a semiconductor substrate; forming a self-assembled monolayer (SAM) within the opening and over the non-conductive layer; forming a catalytic layer within the opening and over the SAM; filling the opening having the SAM and the catalytic layer with a conductive material to form a plug; and forming a barrier layer on sidewalls of the plug.