Abstract: Embodiments include a high temperature electrode connection assembly for a wafer-processing pedestal. The high temperature electrode connection assembly includes an electrode rod having a cup that mounts to a stud embedded in the pedestal and a plate adapter portion. The assembly also includes a floating plate having an outer surface and an aperture for receiving the electrode rod. The floating plate contacts an inner surface of the pedestal to resist lateral movement of the electrode rods. The assembly also includes an anti-rotation retainer ring that frictionally engages the electrode rod and an anti-rotation post extending from the outer surface of the floating plate. The anti-rotation post limits rotation of the electrode rod with respect to the floating plate.

Abstract: In one aspect, a system includes a generator configured to generate and tune a frequency of a supply signal. The system includes an auto-matching network configured to receive the supply signal and to generate an impedance-matched signal for use in powering a plasma system. In some implementations, during a first stage of an impedance matching operation, the generator is configured to tune the frequency of the supply signal until the generator identifies a frequency for which the reactance of the generator and the reactance of the load are best matched. In some implementations, during a second stage of the impedance matching operation, the auto-matching network is configured to tune a tuning element within the auto-matching network until the auto-matching network identifies a tuning of the tuning element for which the resistance of the generator and the resistance of the load are best matched.

Abstract: Exposed copper regions on a semiconductor substrate can be etched by a wet etching solution comprising (i) one or more complexing agents selected from the group consisting of bidentate, tridentate, and quadridentate complexing agents; and (ii) an oxidizer, at a pH of between about 5 and 12. In many embodiments, the etching is substantially isotropic and occurs without visible formation of insoluble species on the surface of copper. The etching is useful in a number of processes in semiconductor fabrication, including for partial or complete removal of copper overburden, for planarization of copper surfaces, and for forming recesses in copper-filled damascene features. Examples of suitable etching solutions include solutions comprising a diamine (e.g., ethylenediamine) and/or a triamine (e.g., diethylenetriamine) as bidentate and tridentate complexing agents respectively and hydrogen peroxide as an oxidizer.

Abstract: Porogen accumulation in a UV-cure chamber is reduced by removing outgassed porogen through a heated outlet while purge gas is flowed across a window through which a wafer is exposed to UV light. A purge ring having specific major and minor exhaust to inlet area ratios may be partially made of flame polished quartz to improve flow dynamics. The reduction in porogen accumulation allows more wafers to be processed between chamber cleans, thus improving throughput and cost.

Abstract: A tungsten nucleation film is formed on a surface of a semiconductor substrate by alternatively providing to that surface, reducing gases and tungsten-containing gases. Each cycle of the method provides for one or more monolayers of the tungsten film. The film is conformal and has improved step coverage, even for a high aspect ratio contact hole.

Abstract: Methods and apparatus for isotropically etching a metal from a work piece, while recovering and reconstituting the chemical etchant are described. Various embodiments include apparatus and methods for etching where the recovered and reconstituted etchant is reused in a continuous loop recirculation scheme. Steady state conditions can be achieved where these processes are repeated over and over with occasional bleed and feed to replenish reagents and/or adjust parameters such as pH, ionic strength, salinity and the like.

Abstract: Described are methods of making silicon nitride (SiN) materials on substrates. Improved SiN films made by the methods are also included. One aspect relates to depositing chlorine (Cl)-free conformal SiN films. In some embodiments, the SiN films are Cl-free and carbon (C)-free. Another aspect relates to methods of tuning the stress and/or wet etch rate of conformal SiN films. Another aspect relates to low-temperature methods of depositing high quality conformal SiN films. In some embodiments, the methods involve using trisilylamine (TSA) as a silicon-containing precursor.

Abstract: Method and apparatus for reducing metal oxide surfaces to modified metal surfaces are disclosed. Metal oxide surfaces are reduced to form a film integrated with a metal seed layer on a substrate by exposing the metal oxide surfaces to a reducing gas atmosphere comprising radicals of a reducing gas species. The radicals of the reducing gas species can form from exposing the reducing gas species to ultraviolet radiation and/or a plasma. The substrate is maintained at a temperature below a temperature that produces agglomeration of the metal seed layer during exposure to the reducing gas atmosphere, such as below 150° C. for copper. In some embodiments, the reducing gas species can include at least one of hydrogen, ammonia, carbon monoxide, diborane, sulfite compounds, carbon and/or hydrocarbons, phosphites, and hydrazine.

Abstract: Methods and apparatus for filling gaps on partially manufactured semiconductor substrates with dielectric material are provided. In certain embodiments, the methods include introducing a first process gas into the processing chamber and accumulating a second process gas in an accumulator maintained at a pressure level substantially highest than that of the processing chamber pressure level. The second process gas is then rapidly introduced from the accumulator into the processing chamber. An excess amount of the second process gas may be provided in the processing chamber during the introduction of the second process gas. Flowable silicon-containing films forms on a surface of the substrate to at least partially fill the gaps.

Abstract: Porous ULK film is cured with UV radiation at progressively shorter wavelengths to obtain ULK films quickly at a desired dielectric constant with improved mechanical properties. At longer wavelengths above about 220 nm or about 240 nm, porogen is removed while minimizing silicon-carbon bond formation. At shorter wavelengths, mechanical properties are improved while dielectric constant increases.

Abstract: In a copper electroplating apparatus having separate anolyte and catholyte portions, the concentration of anolyte components (e.g., acid or copper salt) is controlled by providing a diluent to the recirculating anolyte. The dosing of the diluent can be controlled by the user and can follow a pre-determined schedule. For example, the schedule may specify the diluent dosing parameters, so as to prevent precipitation of copper salt in the anolyte. Thus, precipitation-induced anode passivation can be minimized.

Abstract: Methods, systems, and apparatus for plating a metal onto a work piece are described. In one aspect, an apparatus includes a plating chamber, a substrate holder, an anode chamber housing an anode, and an ionically resistive ionically permeable element positioned between a substrate and the anode chamber during electroplating. The anode chamber may be movable with respect to the ionically resistive ionically permeable element to vary a distance between the anode chamber and the ionically resistive ionically permeable element during electroplating. The anode chamber may include an insulating shield oriented between the anode and the ionically resistive ionically permeable element, with opening in a central region of the insulating shield.

Abstract: Methods and apparatuses for filling high aspect ratio features with tungsten-containing materials are provided. The method involves providing a partially fabricated semiconductor substrate and depositing a tungsten-containing layer on the substrate surface to partially fill one or more high aspect ratio features. The method continues with selective removal of a portion of the deposited layer such that more material is removed near the feature opening than inside the feature. In certain embodiments, removal may be performed at mass-transport limited conditions with less etchant available inside the feature than near its opening. Etchant species are activated before being introduced into the processing chamber and/or while inside the chamber. In specific embodiments, recombination of the activated species is substantially limited and/or controlled during removal, e.g., operation is performed at less than about 250° C. and/or less than about 5 Torr.

Abstract: Methods, apparatus, and systems for depositing tensile or compressive tungsten films are described. In one aspect, a method includes providing a substrate to a chamber. The substrate has a field region and a feature recessed from the field region. Then, the substrate is exposed to an organometallic tungsten precursor. The organometallic tungsten precursor not adsorbed onto the substrate is removed from the chamber. The substrate is treated with a first treatment including a heat treatment or a plasma treatment to form a tungsten layer on the substrate. After treating the substrate, residual gasses are removed from the chamber. The tungsten layer on the substrate is treated with a second treatment including a heat treatment or a plasma treatment.

Abstract: Provided are methods and systems for removing a native silicon oxide layer on a wafer. In a non-sequential approach, a wafer is provided with a native silicon oxide layer on a polysilicon layer. An etchant including a hydrogen-based species and a fluorine-based species is introduced, exposed to a plasma, and flowed onto the wafer at a relatively low temperature. The wafer is then heated to a slightly elevated temperature to substantially remove the native oxide layer. In a sequential approach, a wafer is provided with a native silicon oxide layer. A first etchant including a hydrogen-based species and a fluorine-based species is flowed onto the wafer. Then the wafer is heated to a slightly elevated temperature, a second etchant is flowed towards the wafer, and the second etchant is exposed to a plasma to complete the removal of the native silicon oxide layer and to initiate removal of another layer such as a polysilicon layer.

Abstract: A temperature controlled showerhead assembly for chemical vapor deposition (CVD) chambers enhances heat dissipation to provide accurate temperature control of the showerhead face plate and maintain temperatures substantially lower than surrounding components. Heat dissipates by conduction through a showerhead stem and removed by the heat exchanger mounted outside of the vacuum environment. Heat is supplied by a heating element inserted into the steam of the showerhead. Temperature is controlled using feedback supplied by a temperature sensor installed in the stem and in thermal contact with the face plate.

Abstract: Apparatus and methods for electroplating are described. Apparatus described herein include anode supports including positioning mechanisms that maintain a consistent distance between the surface of the wafer and the surface of a consumable anode during plating. Greater uniformity control is achieved.

Abstract: Methods described herein manage wafer entry into an electrolyte so that air entrapment due to initial impact of the wafer and/or wafer holder with the electrolyte is reduced and the wafer is moved in such a way that an electrolyte wetting wave front is maintained throughout immersion of the wafer also minimizing air entrapment.

Abstract: Methods of forming a film stack may include the plasma accelerated deposition of a silicon nitride film formed from the reaction of nitrogen containing precursor with silicon containing precursor, the plasma accelerated substantial elimination of silicon containing precursor from the processing chamber, the plasma accelerated deposition of a silicon oxide film atop the silicon nitride film formed from the reaction of silicon containing precursor with oxidant, and the plasma accelerated substantial elimination of oxidant from the processing chamber. Process station apparatuses for forming a film stack of silicon nitride and silicon oxide films may include a processing chamber, one or more gas delivery lines, one or more RF generators, and a system controller having machine-readable media with instructions for operating the one or more gas delivery lines, and the one or more RF generators.

Abstract: Techniques, systems, and apparatuses for performing carbon gap-fill in semiconductor wafers are provided. The techniques may include performing deposition-etching operations in a cyclic fashion to fill a gap feature with carbon. A plurality of such deposition-etching cycles may be performed, resulting in a localized build-up of carbon film on the top surface of the semiconductor wafer near the gap feature. An ashing operation may then be performed to preferentially remove the built-up material from the top surface of the semiconductor wafer. Further groups of deposition-etching cycles may then be performed, interspersed with further ashing cycles.