Abstract: Methods of forming copper interconnects are described. A doped tantalum nitride layer formed on a copper layer on a substrate has a first amount of dopant. The doped tantalum nitride layer is exposed to a plasma comprising one or more of helium or neon to form a treated doped tantalum nitride layer with a decreased amount of dopant. Apparatus for performing the methods are also described.

Abstract: A contact stack of a semiconductor device comprises: a source/drain region; a metal silicide layer above the source/drain region; a metal cap layer directly on the metal silicide layer; and a conductor on the metal cap layer. A method comprises: depositing a metal silicide layer in a feature of a substrate; in the absence of an air break after the depositing of the metal silicide layer, preparing a metal cap layer directly on the metal silicide layer; and depositing a conductor on the metal cap layer.

Abstract: Embodiments of a process chamber are provided herein. In some embodiments, a process chamber includes a chamber body having an interior volume, a substrate support disposed in the interior volume, a target disposed within the interior volume and opposing the substrate support, a process shield disposed in the interior volume and having an upper portion surrounding the target and a lower portion surrounding the substrate support, the upper portion having an inner diameter that is greater than an outer diameter of the target to define a gap between the process shield and the target, and a gas inlet to provide a gas to the interior volume through the gap or across a front opening of the gap to substantially prevent particles from the interior volume from entering the gap during use.

Abstract: Methods and apparatus for processing a substrate are provided herein. A method, for example, includes igniting a plasma at a first pressure within a processing volume of a process chamber; depositing sputter material from a target disposed within the processing volume while decreasing the first pressure to a second pressure within a first time frame while maintaining the plasma; continuing to deposit sputter material from the target while decreasing the second pressure to a third pressure within a second time frame less than the first time frame while maintaining the plasma; and continuing to deposit sputter material from the target while maintaining the third pressure for a third time frame that is greater than or equal to the second time frame while maintaining the plasma.

Abstract: In some embodiments, a method of processing a substrate disposed atop a substrate support in a physical vapor deposition process chamber includes: (a) forming a plasma from a process gas within a processing region of the physical vapor deposition chamber, wherein the process gas comprises an inert gas and a hydrogen-containing gas to sputter silicon from a surface of a target within the processing region of the physical vapor deposition chamber; and (b) depositing an amorphous silicon layer atop a first layer on the substrate, wherein adjusting the flow rate of the hydrogen containing gas tunes the optical properties of the deposited amorphous silicon layer.

Abstract: Methods and apparatus for method for filling a feature with copper. In some embodiments, the methods include: (a) depositing a first cobalt layer via a physical vapor deposition (PVD) process atop a substrate field and atop a sidewall and a bottom surface of a feature disposed in a substrate to form a first cobalt portion atop the substrate field and a second cobalt portion atop the sidewall; (b) depositing copper atop the first cobalt portion atop the substrate field; and (c) flowing the copper disposed atop the first cobalt portion atop the substrate field over the second cobalt portion and into the feature, wherein the first cobalt portion atop the substrate field reduces the mobility of copper compared to the mobility of copper over the second cobalt portion.

Abstract: Methods and apparatus for filling features on a substrate are provided herein. In some embodiments, a method of filling features on a substrate includes: depositing a first metallic material on the substrate and within a feature disposed in the substrate in a first process chamber via a chemical vapor deposition (CVD) process at a first temperature; depositing a second metallic material on the first metallic material in a second process chamber at a second temperature and at a first bias power to form a seed layer of the second metallic material; etching the seed layer in the second process chamber at a second bias power greater than the first bias power to form an intermix layer within the feature comprising the first metallic material and the second metallic material; and heating the substrate to a third temperature greater than the second temperature, causing a reflow of the second metallic material.

Abstract: Described are methods for doping barrier layers such as tantalum (Ta), tantalum nitride (TaN), tantalum carbide (TaC), niobium (Nb), niobium nitride (NbN), manganese (Mn), manganese nitride (MnN), titanium (Ti), titanium nitride (TiN), molybdenum (Mo), and molybdenum nitride (MoN), and the like. Dopants may include one or more of one or more of ruthenium (Ru), manganese (Mn), niobium (Nb), cobalt (Co), vanadium (V), copper (Cu), aluminum (Al), carbon (C), oxygen (O), silicon (Si), molybdenum (Mo), and the like. The doped barrier layer provides improved adhesion at a thickness of less than about 15 ?.

Abstract: Apparatuses and methods to provide electronic devices having metal films are provided. Some embodiments of the disclosure utilize a metallic tungsten layer as a liner that is filled with a metal film comprising cobalt. The metallic tungsten layer has good adhesion to the cobalt leading to enhanced cobalt gap-fill performance.

Abstract: Electronic devices and methods of forming electronic devices using a ruthenium or doped ruthenium liner and cap layer are described. A liner with a ruthenium layer and a cobalt layer is formed on a barrier layer. A conductive fill forms a second conductive line in contact with the first conductive line.

Abstract: Methods and apparatus for processing a substrate are provided herein. A method, for example, includes igniting a plasma at a first pressure within a processing volume of a process chamber; depositing sputter material from a target disposed within the processing volume while decreasing the first pressure to a second pressure within a first time frame while maintaining the plasma; continuing to deposit sputter material from the target while decreasing the second pressure to a third pressure within a second time frame less than the first time frame while maintaining the plasma; and continuing to deposit sputter material from the target while maintaining the third pressure for a third time frame that is greater than or equal to the second time frame while maintaining the plasma.

Abstract: Methods and apparatus for processing substrates are disclosed. In some embodiments, a process chamber for processing a substrate includes: a body having an interior volume and a target to be sputtered, the interior volume including a central portion and a peripheral portion; a substrate support disposed in the interior volume opposite the target and having a support surface configured to support the substrate; a collimator disposed in the interior volume between the target and the substrate support; a first magnet disposed about the body proximate the collimator; a second magnet disposed about the body above the support surface and entirely below the collimator and spaced vertically below the first magnet; and a third magnet disposed about the body and spaced vertically between the first magnet and the second magnet. The first, second, and third magnets are configured to generate respective magnetic fields to redistribute ions over the substrate.

Abstract: A method of filling structures on a substrate uses a semi-dynamic reflow process. The method may include depositing a metallic material on the substrate at a first temperature, heating the substrate to a second temperature higher than the first temperature wherein heating of the substrate causes a static reflow of the deposited metallic material on the substrate, stopping heating of the substrate, and depositing additional metallic material on the substrate causing a dynamic reflow of the deposited additional metallic material on the substrate. RF bias power may be applied during the dynamic reflow to facilitate in maintaining the temperature of the substrate.

Abstract: Methods of forming copper interconnects are described. A doped tantalum nitride layer formed on a copper layer on a substrate has a first amount of dopant. The doped tantalum nitride layer is exposed to a plasma comprising one or more of helium or neon to form a treated doped tantalum nitride layer with a decreased amount of dopant. Apparatus for performing the methods are also described.

Abstract: Embodiments of the disclosure relate to methods for enlarging the opening width of substrate features by reducing the overhang of deposited films. Some embodiments of the disclosure utilize a highly energetic bias pulse to etch the deposited film near the opening of the substrate feature. Some embodiments of the disclosure etch the deposited film without damaging the underlying substrate.

Abstract: A method of filling structures on a substrate uses a semi-dynamic reflow process. The method may include depositing a metallic material on the substrate at a first temperature, heating the substrate to a second temperature higher than the first temperature wherein heating of the substrate causes a static reflow of the deposited metallic material on the substrate, stopping heating of the substrate, and depositing additional metallic material on the substrate causing a dynamic reflow of the deposited additional metallic material on the substrate. RF bias power may be applied during the dynamic reflow to facilitate in maintaining the temperature of the substrate.

Abstract: Methods and apparatus for processing a substrate include cleaning and self-assembly monolayer (SAM) formation for subsequent reverse selective atomic layer deposition. An apparatus may include a process chamber with a processing volume and a substrate support including a pedestal, a remote plasma source fluidly coupled to the process chamber and configured to produce radicals or ionized gas mixture with radicals that flow into the processing volume to remove residue or oxides from a surface of the substrate, a first gas delivery system with a first ampoule configured to provide at least one first chemical into the processing volume to produce a SAM on the surface of the substrate, a heating system located in the pedestal and configured to heat a substrate by flowing gas on a backside of the substrate, and a vacuum system fluidly coupled to the process chamber and configured to control heating of the substrate.

Abstract: Described is a process to clean up junction interfaces for fabricating semiconductor devices involving forming low-resistance electrical connections between vertically separated regions. An etch can be performed to remove silicon oxide on silicon surface at the bottom of a recessed feature. Described are methods and apparatus for etching up the bottom oxide of a hole or trench while minimizing the effects to the underlying epitaxial layer and to the dielectric layers on the field and the corners of metal gate structures. The method for etching features involves a reaction chamber equipped with a combination of capacitively coupled plasma and inductive coupled plasma. CHxFy gases and plasma are used to form protection layer, which enables the selectively etching of bottom silicon dioxide by NH3—NF3 plasma. Ideally, silicon oxide on EPI is removed to ensure low-resistance electric contact while the epitaxial layer and field/corner dielectric layers are—etched only minimally or not at all.

Abstract: Described are methods for doping barrier layers such as tantalum (Ta), tantalum nitride (TaN), tantalum carbide (TaC), niobium (Nb), niobium nitride (NbN), manganese (Mn), manganese nitride (MnN), titanium (Ti), titanium nitride (TiN), molybdenum (Mo), and molybdenum nitride (MoN), and the like. Dopants may include one or more of one or more of ruthenium (Ru), manganese (Mn), niobium (Nb), cobalt (Co), vanadium (V), copper (Cu), aluminum (Al), carbon (C), oxygen (O), silicon (Si), molybdenum (Mo), and the like. The doped barrier layer provides improved adhesion at a thickness of less than about 15 ?.

Abstract: Described are microelectronic device comprising a dielectric layer formed on a substrate, a feature 206 comprising a gap defined in the dielectric layer, a barrier layer on the dielectric layer, a two metal liner film on the barrier layer and a gap fill metal on the two metal liner. Embodiments provide a method of forming an microelectronic device comprising the two metal liner film on the barrier layer.