Embodiments of the present invention provide a method for removing a barrier layer of a metal interconnection on a wafer, which remove a single-layer metal ruthenium barrier layer. A method comprises: oxidizing step, is to oxidize the single-layer metal ruthenium barrier layer into a ruthenium oxide layer by electrochemical anodic oxidation process; oxide layer etching step, is to etch the ruthenium oxide layer with etching liquid to remove the ruthenium oxide layer. The present invention also provides a method for removing a barrier layer of a metal interconnection on a wafer, using in a structure of a process node of 10 nm and below, wherein the structure comprises a substrate, a dielectric layer, a barrier layer and a metal layer, the dielectric layer is deposited on the substrate and recessed areas are formed on the dielectric layer, the barrier layer is deposited on the dielectric layer, the metal layer is deposited on the barrier layer, wherein the metal layer is a copper layer, the barrier layer is a single-layer metal ruthenium layer, and the method comprises: thinning step, is to thin the metal layer; removing step, is to remove the metal layer; oxidizing step, is to oxidize the barrier layer, and the oxidizing step uses an electrochemical anodic oxidation process; oxide layer etching step, is to etch the oxidized barrier layer.

A method of making a semiconductor structure includes defining a first recess in an insulation layer. The method further includes forming a protection layer along a sidewall of the first recess. The method further includes forming a first conductive line in the first recess and in direct contact with the protection layer. The method further includes depositing a first insulation material over the first conductive line. The method further includes defining a second recess in the first insulation material. The method further includes forming a second conductive line in the second recess. The method further includes forming a via extending from the second conductive line, wherein the via directly contacts a sidewall of the protection layer.

The present technology relates to a semiconductor device and a method of manufacturing the semiconductor device. The semiconductor device includes a stack structure including a plurality of interlayer insulating layers and a plurality of gate conductive layers that are alternately stacked, a channel plug at least partially passing through the stack structure on a cell region, and a plurality of support structures at least partially passing through the stack structure on a contact region.

Integrated circuit structures having deep via structures, and methods of fabricating integrated circuit structures having deep via structures, are described. For example, an integrated circuit structure includes a plurality of horizontally stacked nanowires. A gate structure is over the plurality of horizontally stacked nanowires. An epitaxial source or drain structure is at an end of the plurality of horizontally stacked nanowires. A conductive trench contact structure is vertically over the epitaxial source or drain structure. A conductive via is vertically beneath and extends into the conductive trench contact structure. The conductive via has a first width beneath the epitaxial source or drain structure less than a second width laterally adjacent to the epitaxial source or drain structure.

An integrated circuit structure includes a first interconnect layer including a first dielectric material. The first dielectric material has a first recess therein, the first recess having a first opening. The integrated circuit structure further includes a second interconnect layer above the first interconnect layer. The second interconnect layer includes a second dielectric material that has a second recess therein. The second recess has a second opening. In an example, at least a portion of the first opening of the first recess abuts and overlaps with at least a portion of the second opening of the second recess. In an example, a continuous conformal layer is on walls of the first and second recesses, and a continuous body of conductive material is within the first and second recesses.

An integrated circuit includes a first and second power rail, a set of active regions, a first set of conductive lines and a first set of vias between the set of active regions and the first set of conductive lines. The first power rail being configured to supply a first supply voltage and being on a first metal layer of a back-side of a substrate. The second power rail being configured to supply a second supply voltage, and being on the first metal layer. The set of active regions being on a first level of a front-side of the substrate opposite from the back-side, overlapping and being electrically coupled to the first and second power rail. The first set of conductive lines being on a second metal layer of the back-side of the substrate, and being overlapped by the set of active regions.

A semiconductor structure includes a substrate and a plurality of word lines. The substrate includes an array region, a periphery region surrounding the array region, and a dummy region between the array region and the periphery region. The array region has a plurality of active regions that are separated from each other by an isolation structure. The dummy region has a dummy pattern. The word lines are buried in the substrate. Each word line extends in the first direction, and the word lines are arranged in the second direction. Each word line has a dummy extending portion that extends into the substrate at the intersection with the dummy pattern. Those dummy extending portions of the word lines are arranged in the second direction.

Methods used in electronic device manufacturing and, more particularly, to methods used for forming metal containing interconnect features in a semiconductor device. In one aspect, a method of forming a boron nitride layer on a metal surface is provided. The method includes exposing a surface of a metal layer to a nitrogen-containing plasma to form a metal nitride layer on the surface. The method further includes performing a chemical vapor deposition (CVD) soak process in which the metal nitride layer is exposed to a boron (B)-containing precursor gas, form a boron nitride monolayer.

A semiconductor device includes a field effect transistor having source/drain regions, the source/drain regions having a source/drain region width. Backside contacts are connected to the source/drain regions. The backside contacts have a dimension greater than the source/drain region width. Metal lines are connected to the backside contacts. The metal lines have a gap therebetween and include a metal line width. The metal lines further include metal line extensions that have an extension width that is less than the metal line width and extends beyond the metal line width to increase tip to tip distance between the metal lines while maintaining a pitch across the gap.

A semiconductor device structure, along with methods of forming such, are described. The semiconductor device structure includes a device, a first dielectric material disposed over the device, and an opening is formed in the first dielectric material. The semiconductor device structure further includes a conductive structure disposed in the opening, and the conductive structure includes a first sidewall. The semiconductor device structure further includes a surrounding structure disposed in the opening, and the surrounding structure surrounds the first sidewall of the conductive structure. The surrounding structure includes a first spacer layer and a second spacer layer adjacent the first spacer layer. The first spacer layer is separated from the second spacer layer by an air gap.