A method for patterning a metal layer includes depositing a hard mask layer on a metal layer, depositing a first patterned layer on the hard mask layer, forming a first set of sidewall spacers on sidewalls of features of the first patterned layer, forming a second set of sidewall spacers on sidewalls of the first set of sidewall spacers, removing the first set of sidewall spacers, and performing a reactive ion etching process to pattern portions of the metal layer exposed through the first patterned layer and the second set of sidewall spacers.

Self-aligned pitch split techniques for metal wiring involving a hybrid (subtractive patterning/damascene) metallization approach are provided. In one aspect, a method for forming a metal wiring layer on a wafer includes the following steps. A copper layer is formed on the wafer. A patterned hardmask is formed on the copper layer. The copper layer is subtractively patterned using the patterned hardmask to form a plurality of first copper lines. Spacers are formed on opposite sides of the first copper lines. A planarizing dielectric material is deposited onto the wafer, filling spaces between the first copper lines. One or more trenches are etched in the planarizing dielectric material. The trenches are filled with copper to form a plurality of second copper lines that are self-aligned with the first copper lines. An electronic device is also provided.

A method of selectively locating a barrier layer on a substrate includes forming a barrier layer on a surface of the substrate. The barrier layer comprises of a metal element and a non-metal element. The barrier layer may also be formed from a metal element and non-metal element. The method further includes forming an electrically conductive film layer on the barrier layer, and forming a metallic portion in the electrically conductive film layer. The method further includes selectively ablating portions of the barrier layer from the dielectric layer to selectively locate place the barrier layer on the substrate.

A method and structure for forming a barrier-free interconnect layer includes patterning a metal layer disposed over a substrate to form a patterned metal layer including one or more trenches. In some embodiments, the method further includes selectively depositing a barrier layer on metal surfaces of the patterned metal layer within the one or more trenches. In some examples, and after selectively depositing the barrier layer, a dielectric layer is deposited within the one or more trenches. Thereafter, the selectively deposited barrier layer may be removed to form air gaps between the patterned metal layer and the dielectric layer.

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.

Provided is a method of forming an interconnect structure including: forming a via; forming a first barrier layer to at least cover a top surface and a sidewall of the via; forming a first dielectric layer on the first barrier layer; performing a planarization process to remove a portion of the first dielectric layer and a portion of the first barrier layer, thereby exposing the top surface of the via; forming a second dielectric layer on the first dielectric layer, wherein the second dielectric layer has an opening exposing the top surface of the via; forming a blocking layer on the top surface of the via; forming a second barrier layer on the second dielectric layer; removing the blocking layer to expose the top surface of the via; and forming a conductive feature in the opening, wherein the conductive feature is in contact with the top surface of the via.

Semiconductor devices may include a diffusion prevention insulation pattern, a plurality of conductive patterns, a barrier layer, and an insulating interlayer. The diffusion prevention insulation pattern may be formed on a substrate, and may include a plurality of protrusions protruding upwardly therefrom. Each of the conductive patterns may be formed on each of the protrusions of the diffusion prevention insulation pattern, and may have a sidewall inclined by an angle in a range of about 80 degrees to about 135 degrees to a top surface of the substrate. The barrier layer may cover a top surface and the sidewall of each if the conductive patterns. The insulating interlayer may be formed on the diffusion prevention insulation pattern and the barrier layer, and may have an air gap between neighboring ones of the conductive patterns.

In one embodiment, a method manufactures a semiconductor device including metallizations having peripheral portions with one or more underlying layers having marginal regions extending facing the peripheral portions. The method includes: providing a sacrificial layer to cover the marginal regions of the underlying layer, providing the metallizations while the marginal regions of the underlying layer are covered by the sacrificial layer, and removing the sacrificial layer so that the marginal regions of the underlying layer extend facing the peripheral portions in the absence of contact interface therebetween, thereby avoiding thermo-mechanical stresses.

A low resistance middle-of-line interconnect structure is formed without liner layers. A contact metal layer is deposited on source/drain regions of field-effect transistors and directly on the surfaces of trenches within a dielectric layer using plasma enhancement. Contact metal fill is subsequently provided by thermal chemical vapor deposition. The use of low-resistivity metal contact materials such as ruthenium is facilitated by the process. The process further facilitates the formation of metal silicide regions on the source/drain regions.

Integrated circuit devices and methods of forming the same are provided. A method according to the present disclosure includes providing a workpiece including a semiconductor substrate, a first ILD layer over the semiconductor substrate, and a first metal feature in the first ILD layer; depositing a second metal feature over the workpiece such that the second metal feature is electrically coupled to the first metal feature; patterning the second metal feature to form a first trench adjacent to the first metal feature; depositing a blocking layer over the workpiece, wherein the blocking layer selectively attaches to the first ILD layer; depositing a barrier layer over the workpiece, wherein the barrier layer selectively forms over the second metal feature relative to the first ILD layer; and depositing a second ILD layer over the workpiece.