A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers. The electrically conductive layers include an intermetallic alloy of aluminum and at least one metal other than aluminum. Memory openings vertically extend through the alternating stack. Memory opening fill structures are located in a respective one of the memory openings and include a respective vertical semiconductor channel and a respective vertical stack of memory elements.

A semiconductor device includes: a semiconductor substrate; an upper surface electrode formed on an upper surface side of the semiconductor substrate; an insulating film formed on the upper surface side of the semiconductor substrate; and a lower surface electrode formed on a lower surface side of the semiconductor substrate and having a larger area than that of the upper surface electrode, wherein the upper surface electrode and the lower surface electrode are electrodes having a compressive stress.

Provided are an interconnect structure and an electronic device including the interconnect structure. The interconnect structure may include a dielectric layer including a trench; a conductive line in the trench; and a first cap layer on an upper surface of the conductive line. The first cap layer may include a graphene-metal composite including graphene and a metal mixed with each other.

An interconnection structure, along with methods of forming such, are described. The structure includes a dielectric layer, a first conductive feature disposed in the dielectric layer, and a conductive layer disposed over the dielectric layer. The conductive layer includes a first portion and a second portion adjacent the first portion, and the second portion of the conductive layer is disposed over the first conductive feature. The structure further includes a first barrier layer in contact with the first portion of the conductive layer, a second barrier layer in contact with the second portion of the conductive layer, and a support layer in contact with the first and second barrier layers. An air gap is located between the first and second barrier layers, and the dielectric layer and the support layer are exposed to the air gap.

A metal structure includes a patterned molybdenum tantalum oxide layer and a patterned metal layer. The patterned molybdenum tantalum oxide layer is disposed on a first substrate, in which the patterned molybdenum tantalum oxide layer includes about 2 to 12 atomic percent of tantalum. Both of an atomic percent of molybdenum and an atomic percent of oxygen of the patterned molybdenum tantalum oxide layer are greater than the atomic percent of tantalum of the patterned molybdenum tantalum oxide layer. The patterned metal layer is disposed on the patterned molybdenum tantalum oxide layer.

An interlayer insulating film has via holes. A sidewall conductive layer is arranged along a sidewall surface of one via hole and contains one or more kinds selected from a group including tungsten, titanium, titanium nitride, tantalum and molybdenum. A second metal wiring layer is embedded in one via hole and contains aluminum. A plug layer is embedded in the other via hole and contains one or more kinds selected from the group including tungsten, titanium, titanium nitride, tantalum and molybdenum.

A method of making a semiconductor structure includes depositing a first passivation material between adjacent conductive elements on a substrate, wherein a bottommost surface of the first passivation material is coplanar with a bottommost surface of each of the adjacent conductive elements. The method further includes depositing a second passivation material on the substrate, wherein the second passivation material contacts a sidewall of each of the adjacent conductive elements and a sidewall of the first passivation material, a bottommost surface of the second passivation material is coplanar with the bottommost surface of each of the adjacent conductive elements, and the second passivation material is different from the first passivation material.

To provide a miniaturized semiconductor device with low power consumption. A method for manufacturing a wiring layer includes the following steps: forming a second insulator over a first insulator; forming a third insulator over the second insulator; forming an opening in the third insulator so that it reaches the second insulator; forming a first conductor over the third insulator and in the opening; forming a second conductor over the first conductor; and after forming the second conductor, performing polishing treatment to remove portions of the first and second conductors above a top surface of the third insulator. An end of the first conductor is at a level lower than or equal to the top level of the opening. The top surface of the second conductor is at a level lower than or equal to that of the end of the first conductor.

A semiconductor device includes a substrate, a first conductive feature over a portion of the substrate, and an etch stop layer over the substrate and the first conductive feature. The etch stop layer includes a silicon-containing dielectric (SCD) layer and a metal-containing dielectric (MCD) layer over the SCD layer. The semiconductor device further includes a dielectric layer over the etch stop layer, and a second conductive feature in the dielectric layer. The second conductive feature penetrates the etch stop layer and electrically connects to the first conductive feature.

In various embodiments a method for manufacturing a metallization layer on a substrate is provided, wherein the method may include providing a structured layer of a catalyst material on the substrate, the catalyst material may include a first layer of material arranged over the substrate and a second layer of material arranged over the first layer of material, wherein the structured layer of catalyst material having a first set of regions including the catalyst material over the substrate and a second set of regions free of the catalyst material over the substrate, and forming a plurality of groups of nanotubes over the substrate, each group of the plurality of groups of nanotubes includes a plurality of nanotubes formed over a respective region in the first set of regions.