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 method includes forming one or more vias in a first layer, forming one or more vias in at least a second layer different than the first layer, aligning at least a first via in the first layer with at least a second via in the second layer, and bonding the first layer to the second layer by filling the first via and the second via with solder material using injection molded soldering.

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.

A method includes bonding a die to a substrate, where the substrate has a first redistribution structure, the die has a second redistribution structure, and the first redistribution structure is bonded to the second redistribution structure. A first isolation material is formed over the substrate and around the die. A first conductive via is formed, extending from a first surface of the substrate, where the first surface is opposite the second redistribution structure, the first conductive via contacting a first conductive element in the second redistribution structure. Forming the first conductive via includes patterning an opening in the substrate, extending the opening to expose the first conductive element, where extending the opening includes using a portion of a second conductive element in the first redistribution structure as an etch mask, and filling the opening with a conductive material.

A method is provided for fabricating a semiconductor structure. The method includes providing a semiconductor substrate; forming an initial metal layer; simultaneously forming a plurality of discrete first metal layers and openings by etching the initial metal layer; forming a plurality of sidewalls covering the side surface of the first metal layers; and forming a plurality of second metal layers to fill the openings.

A method for fabricating a semiconductor device is provided. A substrate having a dummy gate thereon is prepared. A spacer is disposed on a sidewall of the dummy gate. A source/drain region is disposed adjacent to the dummy gate. A sacrificial layer is then formed on the source/drain region. A cap layer is then formed on the sacrificial layer. A top surface of the cap layer is coplanar with a top surface of the dummy gate. A replacement metal gate (RMG) process is performed to transform the dummy gate into a replacement metal gate. An opening is then formed in the cap layer to expose a top surface of the sacrificial layer. The sacrificial layer is removed through the opening, thereby forming a lower contact hole exposing a top surface of the source/drain region. A lower contact plug is then formed in the lower contact hole.

A method for manufacturing a semiconductor device includes forming a trench in at least one dielectric layer; and forming an interconnect structure in the trench, wherein forming the interconnect structure includes forming a first conductive layer on a bottom surface of the trench, and partially filling the trench, and forming a second conductive layer on the first conductive layer, and filling a remaining portion of the trench, wherein the second conductive layer comprises a different material from the first conductive layer, and wherein an amount of the first conductive layer in the trench is controlled so that an aspect ratio of the second conductive layer has a value that is determined to result in columnar grain boundaries in the second conductive layer.

Methods of forming memory structures are discussed. Specifically, methods of forming 3D NAND devices are discussed. Some embodiments form memory structures with a metal nitride barrier layer, an α-tungsten layer, and a bulk metal material. The barrier layer comprises a TiXN or TaXN material, where X comprises a metal selected from one or more of aluminum (Al), silicon (Si), tungsten (W), lanthanum (La), yttrium (Yt), strontium (Sr), or magnesium (Mg).

Disclosed herein is a semiconductor device, including: a first substrate including a first electrode, and a first insulating film configured from a diffusion preventing material for the first electrode and covering a periphery of the first electrode, the first electrode and the first insulating film cooperating with each other to configure a bonding face; and a second substrate bonded to and provided on the first substrate and including a second electrode joined to the first electrode, and a second insulating film configured from a diffusion preventing material for the second electrode and covering a periphery of the second electrode, the second electrode and the second insulating film cooperating with each other to configure a bonding face to the first substrate.