The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate; a bottom interconnector layer positioned in the substrate; a bottom dielectric layer positioned on the bottom glue layer; an interconnector structure positioned along the bottom dielectric layer and the bottom glue layer, positioned on the bottom interconnector layer, and positioned on the bottom dielectric layer; a top glue layer conformally positioned on the bottom dielectric layer and the interconnector structure; a top dielectric layer positioned surrounding the top glue layer. A top surface of the top glue layer and a top surface of the top dielectric layer are substantially coplanar. The top dielectric layer is porous.

A semiconductor device includes a source/drain component of a transistor. A source/drain contact is disposed over the source/drain component. A source/drain via is disposed over the source/drain contact. The source/drain via contains copper. A first liner at least partially surrounds the source/drain via. A second liner at least partially surrounds the first liner. The first liner and the second liner are disposed between the source/drain contact and the source/drain via. The first liner and the second liner have different material compositions.

A semiconductor structure includes a semiconductor substrate, a dielectric layer, a tungsten plug, a conductive plug, and a contact barrier. The dielectric layer is over a semiconductor substrate. The tungsten plug is in the dielectric layer. The conductive plug is on the tungsten plug. The contact barrier includes a sidewall barrier on a sidewall of the conductive plug and a bottom barrier between the conductive plug and the tungsten plug. A thickness of the sidewall barrier is greater than a thickness of the bottom barrier.

A semiconductor structure includes a substrate and a back end of line (BEOL) layer disposed on the substrate. The BEOL layer includes a first dielectric layer, a via conductive portion, a second dielectric layer and a liner. The first dielectric layer has a surface and a via-hole extends from the surface. The via conductive portion is disposed within the via-hole and has a recess recessed relative to the surface. The second dielectric layer is disposed on the first dielectric layer, wherein the second dielectric layer has a metal-trench exposing the recess. The liner is disposed on a sidewall of the metal-trench and separated from the via conductive portion.

Interconnect structures and methods and apparatuses for forming the same are disclosed. In an embodiment, a method includes supplying a process gas to a process chamber; igniting the process gas into a plasma in the process chamber; reducing a pressure of the process chamber to less than 0.3 mTorr; and after reducing the pressure of the process chamber, depositing a conductive layer on a substrate in the process chamber.

A semiconductor structure includes a first dielectric layer over a first conductive line and a second conductive line, a high resistance layer over a portion of the first dielectric layer, a low-k dielectric layer over the second dielectric layer, a second dielectric layer on the high resistance layer, a first conductive via extending through the low-k dielectric layer and the second dielectric layer, and a second conductive via extending through the low-k dielectric layer and the first dielectric layer to the first conductive line. The first conductive via extends into the high resistance layer.

Embodiments provide a method and resulting structure that includes forming an opening in a dielectric layer to expose a metal feature, selectively depositing a metal cap on the metal feature, depositing a barrier layer over the metal cap, and depositing a conductive fill on the barrier layer.

A three-dimensional (3D) metal-insulator-metal capacitor (MIMCAP) includes a plurality of center studs disposed within cavity walls of a plurality of cavities in a top plate. The center studs and the cavity walls are oriented orthogonal to a first metal layer and extend through a first via layer and a second metal layer. Each center stud includes a metal layer stud in the second metal layer stacked on a via layer stud in the first via layer. A dielectric layer is disposed between the center studs and the cavity walls of the plurality of cavities in the top plate. The center studs are coupled to a first electrode, and the top plate is coupled to a second electrode in the interconnect layers. In some examples, the center studs can form vertically oriented cylindrical capacitive elements positioned for high capacitance density.

Metal nitride diffusion barriers may be included between cobalt-based structures and ruthenium-based structures to reduce, minimize, and/or prevent intermixing of cobalt into ruthenium. A metal nitride diffusion barrier layer may include a cobalt nitride (CoN.sub.x), a ruthenium nitride (RuN.sub.x), or another metal nitride that has a bond dissociation energy greater than the bond dissociation energy of cobalt to cobalt (CoCo), and may therefore function as a strong barrier to cobalt migration and diffusion into ruthenium. Moreover, cobalt nitride and ruthenium nitride have lower resistivity relative to other materials such as titanium nitride (TiN), tungsten nitride (WN), and tantalum nitride (TaN). In this way, the metal nitride diffusion barriers are capable of minimizing cobalt diffusion and intermixing into ruthenium-based interconnect structures while maintaining a low contact resistance for the interconnect structures. This may increase semiconductor device performance, may increase semiconductor device yield, and may enable further reductions in interconnect structure size.

Methods of manufacturing interconnect structures as part of a microelectronic device fabrication process are described. Methods of selectively depositing iridium-containing films are also described. The methods include exposing a substrate including a metallic material and a dielectric material to an iridium-containing precursor and a reactant to form the iridium-containing film. The iridium-containing film selectively grows on the metallic material relative to the dielectric material.