Abstract: Embodiments of the present disclosure generally relate to subtractive metals, subtractive metal semiconductor structures, subtractive metal interconnects, and to processes for forming such semiconductor structures and interconnects. In an embodiment, a process for fabricating a semiconductor structure is provided. The process includes performing a degas operation on the semiconductor structure and depositing a liner layer on the semiconductor structure. The process further includes performing a sputter operation on the semiconductor structure, and depositing, by physical vapor deposition, a metal layer on the liner layer, wherein the liner layer comprises Ti, Ta, TaN, or combinations thereof, and a resistivity of the metal layer is about 30 ??·cm or less.

Abstract: Embodiments of the present disclosure generally relate to methods of cleaning a structure and methods of depositing a capping layer in a structure. The method of cleaning a structure includes suppling a cleaning gas, including a first gas including nitrogen (N) and a second gas including fluorine (F), to a bottom surface of a structure. The cleaning gas removes unwanted metal oxide and etch residue from the bottom surface of the structure. The method of depositing a capping layer includes depositing the capping layer over the bottom surface of the structure. The methods described herein reduce the amount of unwanted metal oxides and residue, which improves adhesion of deposited capping layers.

Abstract: Embodiments of the present disclosure are related to improved methods for forming an interconnect structure in a substrate. In one implementation, the method includes forming a barrier layer on exposed surfaces of a feature in a dielectric layer, forming a liner layer on the barrier layer, forming a seed layer on the liner layer, forming a metal fill on the seed layer by a metal fill process and overburdening the feature using an electroplating process, performing a planarization process to expose a top surface of the dielectric layer, and selectively forming a cobalt-aluminum alloy cap layer on the barrier layer, the liner layer, the seed layer, and the metal fill by exposing the substrate to a cobalt-containing precursor and an aluminum-containing precursor.

Abstract: Embodiments of the present disclosure generally relate to subtractive metals, subtractive metal semiconductor structures, subtractive metal interconnects, and to processes for forming such semiconductor structures and interconnects. In an embodiment, a process for fabricating a semiconductor structure is provided. The process includes performing a degas operation on the semiconductor structure and depositing a liner layer on the semiconductor structure. The process further includes performing a sputter operation on the semiconductor structure, and depositing, by physical vapor deposition, a metal layer on the liner layer, wherein the liner layer comprises Ti, Ta, TaN, or combinations thereof, and a resistivity of the metal layer is about 30 ??·cm or less.

Abstract: Embodiments of the present disclosure are related to improved methods for forming an interconnect structure in a substrate. In one implementation, the method includes providing a substrate comprising a metal region and a dielectric region surrounding the metal region, selectively forming a cobalt-containing alloy cap layer on the metal region by exposing the substrate to a first precursor and a second precursor, the first precursor and the second precursor are selected from a group consisting of an aluminum-containing precursor, a cobalt-containing precursor, a ruthenium-containing precursor, a manganese-containing precursor, and a tungsten-containing precursor, wherein the first precursor is different from the second precursor.

Abstract: Methods for forming an interconnections structure on a substrate in a cluster processing system and thermal processing such interconnections structure are provided. In one embodiment, a method for a device structure for semiconductor devices includes forming a barrier layer in an opening formed in a material layer disposed on a substrate, forming an interface layer on the barrier layer, forming a gap filling layer on the interface layer, and performing an annealing process on the substrate, wherein the annealing process is performed at a pressure range greater than 5 bar.

Abstract: Embodiments of the present disclosure generally relate an interconnect structure formed on a substrate and a method of forming the interconnect structure thereon. In one embodiment, a method of forming an interconnect structure includes forming an opening comprising a via and a trench in an insulating structure formed on a substrate, forming a first passivation layer in the opening, removing a portion of the first passivation layer from the opening, and selectively depositing a first metal containing material in the via.

Abstract: Embodiments of the present disclosure generally relate to methods of cleaning a structure and methods of depositing a capping layer in a structure. The method of cleaning a structure includes suppling a cleaning gas, including a first gas including nitrogen (N) and a second gas including fluorine (F), to a bottom surface of a structure. The cleaning gas removes unwanted metal oxide and etch residue from the bottom surface of the structure. The method of depositing a capping layer includes depositing the capping layer over the bottom surface of the structure. The methods described herein reduce the amount of unwanted metal oxides and residue, which improves adhesion of deposited capping layers.

Abstract: In one implementation, a method of forming a cobalt layer on a substrate is provided. The method comprises forming a barrier and/or liner layer on a substrate having a feature definition formed in a first surface of the substrate, wherein the barrier and/or liner layer is formed on a sidewall and bottom surface of the feature definition. The method further comprises exposing the substrate to a ruthenium precursor to form a ruthenium-containing layer on the barrier and/or liner layer. The method further comprises exposing the substrate to a cobalt precursor to form a cobalt seed layer atop the ruthenium-containing layer. The method further comprises forming a bulk cobalt layer on the cobalt seed layer to fill the feature definition.

Abstract: Methods for forming an interconnections structure on a substrate in a cluster processing system and thermal processing such interconnections structure are provided. In one embodiment, a method for a device structure for semiconductor devices includes forming a barrier layer in an opening formed in a material layer disposed on a substrate, forming an interface layer on the barrier layer, forming a gap filling layer on the interface layer, and performing an annealing process on the substrate, wherein the annealing process is performed at a pressure range greater than 5 bar.

Abstract: Embodiments of the present disclosure provide methods and apparatus for forming and patterning features in a film stack disposed on a substrate. In one embodiment, a method for patterning a conductive layer on a substrate includes supplying a gas mixture comprising a chlorine containing gas at a first flow rate to etch a first conductive layer disposed on the substrate, lowing the chlorine containing gas in the first gas mixture to a second flow rate lower than the first flow rate to continue etching the first conductive layer, and increasing the chlorine containing gas in the first gas mixture to a third flow rate greater than the second flow rate to remove the first conductive layer from the substrate.

Abstract: Embodiments of the present disclosure generally relate an interconnect structure formed on a substrate and a method of forming the interconnect structure thereon. In one embodiment, a method of forming an interconnect structure includes forming an opening comprising a via and a trench in an insulating structure formed on a substrate, forming a first passivation layer in the opening, removing a portion of the first passivation layer from the opening, and selectively depositing a first metal containing material in the via.

Abstract: Methods and apparatus for forming a metal silicide as nanowires for back-end interconnection structures for semiconductor applications are provided. In one embodiment, the method includes forming a metal silicide layer on a substrate by a chemical vapor deposition process or a physical vapor deposition process, thermal treating the metal silicide layer in a processing chamber, applying a microwave power in the processing chamber while thermal treating the metal silicide layer; and maintaining a substrate temperature less than 400 degrees Celsius while thermal treating the metal silicide layer. In another embodiment, a method includes supplying a deposition gas mixture including at least a metal containing precursor and a reacting gas on a surface of a substrate, forming a plasma in the presence of the deposition gas mixture by exposure to microwave power, exposing the plasma to light radiation, and forming a metal silicide layer on the substrate from the deposition gas.

Abstract: Methods for forming low resistivity metal silicide interconnects using one or a combination of a physical vapor deposition (PVD) process and an anneal process are described herein. In one embodiment, a method of forming a plurality of wire interconnects includes flowing a sputtering gas into a processing volume of a processing chamber, applying a power to a target disposed in the processing volume, forming a plasma in a region proximate to the sputtering surface of the target, and depositing the metal and silicon layer on the surface of the substrate. Herein, the first target comprises a metal silicon alloy and a sputtering surface thereof is angled with respect to a surface of the substrate at between about 10° and about 50°.

Abstract: Methods for forming a copper seed layer having improved anti-migration properties are described herein. In one embodiment, a method includes forming a first copper layer in a feature, forming a ruthenium layer over the first copper layer in the feature, and forming a second copper layer on the ruthenium layer in the feature. The ruthenium layer substantially locks the copper layer there below in place in the feature, preventing substantial physical migration thereof.

Abstract: Interconnects and methods for forming interconnects are described and disclosed herein. The interconnect contains a stack formed on a substrate having a via and a trench formed therein, a first metal formed from a first material of a first type deposited in the via, and a second metal formed from a second material of a second type deposited in the trench.

Abstract: In one implementation, a method of forming a cobalt layer on a substrate is provided. The method comprises forming a barrier and/or liner layer on a substrate having a feature definition formed in a first surface of the substrate, wherein the barrier and/or liner layer is formed on a sidewall and bottom surface of the feature definition. The method further comprises exposing the substrate to a ruthenium precursor to form a ruthenium-containing layer on the barrier and/or liner layer. The method further comprises exposing the substrate to a cobalt precursor to form a cobalt seed layer atop the ruthenium-containing layer. The method further comprises forming a bulk cobalt layer on the cobalt seed layer to fill the feature definition.

Abstract: Generally, embodiments described herein relate to methods for manufacturing an interconnect structure for semiconductor devices, such as in a dual subtractive etch process. An embodiment is a method for semiconductor processing. A titanium nitride layer is formed over a substrate. A hardmask layer is formed over the titanium nitride layer. The hardmask layer is patterned into a pattern. The pattern is transferred to the titanium nitride layer, where the transferring comprises etching the titanium nitride layer. After transferring the pattern to the titanium nitride layer, the hardmask layer is removed, where the removal comprises performing an oxygen-containing ash process.

Abstract: Methods for depositing a low resistivity nickel silicide layer used in forming an interconnect and electronic devices formed using the methods are described herein. In one embodiment, a method for depositing a layer includes positioning a substrate on a substrate support in a processing chamber, the processing chamber having a nickel target and a silicon target disposed therein, the substrate facing portions of the nickel target and the silicon target each having an angle of between about 10 degrees and about 50 degrees from the target facing surface of the substrate, flowing a gas into the processing chamber, applying an RF power to the nickel target and concurrently applying a DC power to the silicon target, concurrently sputtering silicon and nickel from the silicon and nickel targets, respectively, and depositing a NixSi1-x layer on the substrate, where x is between about 0.01 and about 0.99.

Abstract: Embodiments of the present disclosure provide methods and apparatus for forming and patterning features in a film stack disposed on a substrate. In one embodiment, a method for patterning a conductive layer on a substrate includes supplying a gas mixture comprising a chlorine containing gas at a first flow rate to etch a first conductive layer disposed on the substrate, lowing the chlorine containing gas in the first gas mixture to a second flow rate lower than the first flow rate to continue etching the first conductive layer, and increasing the chlorine containing gas in the first gas mixture to a third flow rate greater than the second flow rate to remove the first conductive layer from the substrate.