A first metal interconnection pattern is formed over a substrate. A spacer layer is selectively deposited on the exposed surfaces of the first metal interconnection pattern. Subsequently, a metal overburden layer is deposited on the spacer layer. The excess portion of the metal overburden layer is removed, i.e., that portion deposited over a top surface of the metal interconnection pattern and the spacer layer. This forms a second metal interconnection pattern. The elements of the second metal interconnection pattern are located between respective elements of the first metal interconnection pattern.

An interconnect layer for a device and methods for fabricating the interconnect layer are provided. The interconnect layer includes first metal structures arranged in a first array in the interconnect layer and second metal structures, arranged in a second array in the interconnect layer. The second array includes at least one metal structure positioned between two metal structures of the first metal structures. The interconnect layer also includes a spacer material formed around each of the first metal structures and the second metal structures and air gaps formed in the spacer material on each side of the first metal structures.

A semiconductor device is provided. The semiconductor device includes: a first interlayer insulating film defining a lower wiring trench; a lower wiring structure including a first lower barrier film which extends along sidewalls of the lower wiring trench, and a lower filling film which is on the first lower barrier film; a second interlayer insulating film on the first interlayer insulating film, the second interlayer insulating film defining an upper wiring trench which exposes at least part of the lower wiring structure; and an upper wiring structure provided in the upper wiring trench and connected to the lower wiring structure. An upper surface of the first lower barrier film is closer to a bottom surface of the lower wiring trench than each of an upper surface of the first interlayer insulating film and an upper surface the lower filling film. The upper surface of the first lower barrier film is concave.

A semiconductor device includes a metal gate structure having sidewall spacers disposed on sidewalls of the metal gate structure. In some embodiments, a top surface of the metal gate structure is recessed with respect to a top surface of the sidewall spacers. The semiconductor device may further include a metal cap layer disposed over and in contact with the metal gate structure, where a first width of a bottom portion of the metal cap layer is greater than a second width of a top portion of the metal cap layer. In some embodiments, the semiconductor device may further include a dielectric material disposed on either side of the metal cap layer, where the sidewall spacers and a portion of the metal gate structure are disposed beneath the dielectric material.

The present disclosure relates to an integrated chip that includes a substrate, a first metal line, and a hybrid metal line. The first metal line includes a first metal material and is within a first interlayer dielectric (ILD) layer over the substrate. The hybrid metal line is also within the first ILD layer. The hybrid metal line includes a pair of first metal segments that comprise the first metal material. The hybrid metal line further includes a second metal segment that comprises a second metal material that is different from the first metal material. The second metal segment is laterally between the pair of first metal segments.

A semiconductor device includes a conductive line disposed within a dielectric layer, a metal layer disposed over and in direct contact with the conductive line, and a metallization layer disposed over the metal layer such that a protruding segment of the metal layer acts as an interface between the conductive line and the metallization layer. The conductive line is copper (Cu) and the metal layer is ruthenium (Ru). The Ru metal layer includes an upper metal layer section and a lower metal layer section.

An semiconductor device includes a first dielectric layer, an etch stop layer, an interconnect structure, and a second dielectric layer. The etch stop layer is over the first dielectric layer. The interconnect structure includes a conductive via in the first dielectric layer and the etch stop layer, a conductive line over the conductive via, an intermediate conductive layer over the conductive line, and a conductive pillar over the intermediate conductive layer. The interconnect structure is electrically conductive at least from a top of the conductive pillar to a bottom of the conductive via. The second dielectric layer surrounds the conductive line, the intermediate conductive layer, and the conductive pillar, wherein a bottom of the second dielectric layer is lower than a top of the conductive line, and a top of the second dielectric layer is higher than the top of the conductive line.

One or more semiconductor arrangements are provided. A semiconductor arrangement includes a first dielectric layer defining a first recess, a first contact in the first dielectric layer, a first metal cap over at least part of the first contact and a second dielectric layer over the first dielectric layer within the first recess and defining an air gap proximate the first contact. One or more methods of forming a semiconductor arrangement are also provided. Such a method includes forming a first metal cap on a first exposed surface of a first contact, the first metal cap having an extension region that extends into a first recess defined in a first dielectric layer and forming a second dielectric layer over the first dielectric layer within the first recess such that an air gap is defined within the second dielectric layer proximate the first contact due to the extension region.

An interconnect structure and a method of forming the interconnect structure are provided. The interconnect structure includes one or more metal lines and one or more top vias in direct contact with a top surface of the one or more metal lines. The interconnect structure also includes a liner formed on sidewalls of the one or more top vias and top portions of the one or more metal lines.

A method of manufacturing an interconnect structure for a semiconductor device is provided. The method includes forming a metal interconnect layer on a substrate. The method includes forming a hardmask on the metal interconnect layer, patterning the metal interconnect layer and hardmask, forming a sacrificial material layer to overfill the patterned metal interconnect layer and hardmask, and selectively removing a portion of the sacrificial layer and the hardmask to form a via opening. The method also includes forming a via on the metal interconnect layer in the via opening by a selective metal growth process.