A method of forming a metal superlattice structure includes depositing, on a substrate, a layer of a first metal with face-centered-cubic (fcc) crystal structure. The method further includes depositing a layer of ruthenium (Ru) metal with fcc crystal structure on the layer of the first metal. The layer of the first metal may cause the layer of ruthenium metal to have fcc crystal structure.

A method for manufacturing an interconnect structure includes providing a substrate structure including a substrate, a first metal layer on the substrate, a dielectric layer on the substrate and covering the first metal layer, and an opening extending to the first metal layer; forming a first barrier layer on a bottom and sidewalls of the opening with a first substrate bias; forming a second barrier layer on the first barrier layer with a second substrate bias, the second substrate bias being greater than the first substrate bias, the first and second barrier layers forming collectively a barrier layer; removing a portion of the barrier layer on the bottom and on the sidewalls of the opening by bombarding the barrier layer with a plasma with a vertical substrate bias; and forming a second metal layer filling the opening.

A film forming method includes: preparing a substrate that includes a base substrate and a first conductive film that is formed on the base substrate; forming, on the first conductive film, a composite layer that includes layers of graphene and includes, as dopant atoms, a transition metal from 4th period to 6th period in a periodic table, excluding lanthanoids, between the layers of graphene; and forming, on the composite layer, a second conductive film which is electrically connected to the first conductive film via the composite layer.

A film deposition method may include preparing a non-planar substrate including a first surface, a second surface, and an inclined surface between the first surface and the second surface; depositing a film having a thickness deviation on the first surface, the second surface, and the inclined surface; and etching the film deposited on the first surface, the second surface, and the inclined surface. A height of the second surface may be different than a height of the first surface.

Implementations of a method of forming semiconductor packages may include: providing a wafer having a plurality of devices, etching one or more trenches on a first side of the wafer between each of the plurality of devices, applying a molding compound to the first side of the wafer to fill the one or more trenches; grinding a second side of the wafer to a desired thickness, and exposing the molding compound included in the one or more trenches. The method may include etching the second side of the wafer to expose a height of the molding compound forming one or more steps extending from the wafer, applying a back metallization to a second side of the wafer, and singulating the wafer at the one or more steps to form a plurality of semiconductor packages. The one or more steps may extend from a base of the back metallization.

A gate-turn-off thyristor is provided. The gate-turn-off thyristor includes a plurality of strips formed by repeatedly arranging a plurality of N-type emitter regions with high doping concentration of an upper transistor on an upper surface of an N-type silicon substrate with high resistivity, wherein a periphery of each strip of the plurality of strips is surrounded with a P-type dense base region bus bar of the upper transistor, a cathode metal layer is disposed on an N-type emitter region of the plurality of N-type emitter regions of the upper transistor, and a P-type base region of the upper transistor is disposed below the N-type emitter region of the upper transistor; a side of the P-type base region of the upper transistor is connected to a P-type dense base region of the upper transistor or a P-type dense base region bus bar of the upper transistor.

Methods and apparatus for processing a substrate are provided. For example, a method includes sputtering a material from a target in a PVD chamber to form a material layer on a layer comprising a feature of the substrate, the feature having an opening width defined by a first sidewall and a second sidewall, the material layer having a greater lateral thickness at the top surface of the layer than a thickness on the first sidewall or the second sidewall within the feature, depositing additional material on the layer by biasing the layer with an RF bias at a low power, etching the material layer from the layer by biasing the layer with an RF bias at a high-power, and repeatedly alternating between the low power and the high-power at a predetermined frequency.

Apparatuses and methods for manufacturing semiconductor memory devices are described. An example method includes: forming a conductive layer and sputtering the conductive layer with gas. The conductive layer includes a first portion having a top surface having a first height; and a second portion having a top surface having a second height lower than the first height. Sputtering the conductive layer with gas may be performed to remove the first portion of the conductive layer and increase the second height of the second portion of the conductive layer concurrently.

An integrated circuit includes a substrate, a transistor over the substrate, a first inter-metal dielectric (IMD) layer over the transistor, a metal via in the first IMD layer, a first 2-D material layer cupping an underside of the metal via, a second IMD layer over the metal via, a metal line in the second IMD layer, and a second 2-D material layer cupping an underside of the metal line. The second 2-D material layer span across the metal via and the first 2-D material layer.

An interconnect structure comprising a low via resistance via structure is disclosed. The via structure comprises a barrier layer on sidewalls and at bottom of the via structure. The interconnect structure also includes a first metal layer. The interconnect structure further includes a second metal layer between the barrier layer at the bottom of the via structure and the first metal layer, wherein the first metal layer and the second metal layer comprise different materials.