Exemplary methods of electroplating may include providing a patterned substrate having at least one opening, where the opening includes one or more sidewalls and a bottom surface. The methods may also include plating a first portion of ruthenium-containing material on the bottom surface of the opening at a first deposition rate and a second portion of ruthenium-containing material on the sidewalls of the opening at a second deposition rate, where the first deposition rate is greater than the second deposition rate. The methods may be used to make integrated circuit devices that include void-free, electrically-conductive lines and columns of ruthenium-containing materials.

A process of smoothing a top surface of a bit line metal of a memory structure to decrease resistance of a bit line stack. The process includes depositing titanium layer of approximately 30 angstroms to 50 angstroms on polysilicon layer on a substrate, depositing first titanium nitride layer of approximately 15 angstroms to approximately 40 angstroms on titanium layer, annealing substrate at a temperature of approximately 700 degrees Celsius to approximately 850 degrees Celsius, depositing second titanium nitride layer of approximately 15 angstroms to approximately 40 angstroms on first titanium nitride layer after annealing, depositing a bit line metal layer of ruthenium on second titanium nitride layer, annealing bit line metal layer at temperature of approximately 550 degrees Celsius to approximately 650 degrees Celsius, and soaking bit line metal layer in hydrogen-based ambient for approximately 3 minutes to approximately 6 minutes during annealing.

Exemplary methods of electroplating a metal with a nanotwin crystal structure are described. The methods may include plating a metal material into at least one opening on a patterned substrate, where at least a portion of the metal material is characterized by a nanotwin crystal structure. The methods may further include polishing an exposed surface of the metal material in the opening to reduce an average surface roughness of the exposed surface to less than or about 1 nm. The polished exposed surface may include at least a portion of the metal material characterized by the nanotwin crystal structure. In additional examples, the nanotwin-phased metal may be nanotwin-phased copper.

An exemplary semiconductor structure includes a substrate defining a first trench; a first refractory metal liner coating the first trench; a heavy metal liner coating the first refractory metal liner; a copper structure filling the first trench over the heavy metal liner; a generally planar capping dielectric layer on top of the substrate and the copper structure; a low-k dielectric layer on top of the capping dielectric layer, wherein the low-k dielectric layer defines a second trench; a second refractory metal liner coating the second trench; a metal line filling the second refractory metal liner; and a metal via protruding from the metal line.

Interconnect structures and method of forming the same are disclosed herein. An exemplary interconnect structure includes a first contact feature in a first dielectric layer, a second dielectric layer over the first dielectric layer, a second contact feature over the first contact feature, a barrier layer between the second dielectric layer and the second contact feature, and a liner between the barrier layer and the second contact feature. An interface between the first contact feature and the second contact feature includes the liner but is free of the barrier layer.

A semiconductor device structure is provided. The semiconductor device structure includes a substrate. The semiconductor device structure includes a gate stack over the substrate. The gate stack includes a gate dielectric layer, a first metal-containing layer, a silicon-containing layer, a second metal-containing layer, and a gate electrode layer sequentially stacked over the substrate. The silicon-containing layer is between the first metal-containing layer and the second metal-containing layer, and the silicon-containing layer is thinner than the second metal-containing layer.

A semiconductor fabrication method that uses a graphene etch stop is disclosed. The method comprises forming a first set of trenches and a second set of trenches in a substrate. The first set of trenches are narrower than the second set of trenches. The method further comprises forming a graphene layer in the first and second sets of trenches. The method further comprises depositing a first conductor in the first and second sets of trenches. The method further comprises removing the first conductor from the second set of trenches using an etching process. The graphene layer acts as an etch stop for the etching process. The method further comprises depositing a second conductor in the second set of trenches. The second conductor is different than the first conductor.

Embodiments of the invention include a multi-layer integrated circuit (IC) structure having a back-end-of-line (BEOL) region that includes a dielectric. A single damascene interconnect is in the BEOL region, wherein the single damascene interconnect includes a first line structure in a first line trench of the BEOL region; and a via structure in a via trench of the BEOL region. The first line structure includes a first line element and a first liner. The via structure includes a via element and a via liner. The first line element is physically coupled to inner walls of the first line trench through the first liner. The via element is physically coupled to inner walls of the via trench through the via liner. The first line element is physically coupled and electrically coupled to the via element at a first-line-via interface.

A graphene barrier layer is disclosed. Some embodiments relate to a graphene barrier layer capable of preventing diffusion from a fill layer into a substrate surface and/or vice versa. Some embodiments relate to a graphene barrier layer that prevents diffusion of fluorine from a tungsten layer into the underlying substrate. Additional embodiments relate to electronic devices which contain a graphene barrier layer.

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 adj acent 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.