Abstract: A method for etching features in a silicon oxide containing etch layer disposed below a patterned mask in a chamber is provided. An etch gas comprising a tungsten containing gas is flowed into the chamber. The etch gas comprising the tungsten containing gas is formed into a plasma. The silicon oxide etch layer is exposed to the plasma formed from the etch gas comprising the tungsten containing gas. Features are etched in the silicon oxide etch layer while exposed to the plasma formed from the etch gas comprising the tungsten containing gas.

Abstract: A method and system for cleaning a surface of a substrate after an etching operation includes determining a plurality of process parameters associated with the surface of the substrate. A plurality of application chemistries are identified based on the process parameters. The plurality of application chemistries includes a first application chemistry as an emulsion having a first immiscible liquid combined with a second immiscible liquid and solid particles distributed within the first immiscible liquid. The plurality of application chemistries including the first application chemistry are applied to the surface of the substrate such that the combined chemistries enhance the cleaning process by substantially removing the particulate and polymer residue contaminants from the surface of the substrate while preserving the characteristics of the features and of the low-k dielectric material through which the features are formed.

Abstract: Apparatus and methods for removing particle contaminants from a solid surface includes providing a layer of a viscoelastic material on the solid surface. The viscoelastic material is applied as a thin film and exhibits substantial liquid-like characteristics. The viscoelastic material at least partially binds with the particle contaminants. A high velocity liquid is applied to the viscoelastic material, such that the viscoelastic material exhibits solid-like behavior. The viscoelastic material is thus dislodged from the solid surface along with the particle contaminants, thereby cleaning the solid surface of the particle contaminants.

Abstract: A substrate is moved below a substrate cleaning module in a direction extending from a leading edge to a trailing edge of the substrate cleaning module. A cleaning material is dispensed downward toward a top surface of the substrate along the leading edge of the substrate cleaning module. A rinsing material is dispensed downward toward the top surface of the substrate along the trailing edge of the substrate cleaning module to generate a rinsing meniscus. Vacuum suction is applied at a vacuum suction location along a bottom surface of the substrate cleaning module and parallel to the leading and trailing edges of the substrate cleaning module. The vacuum location is positioned between a dispense location of the cleaning material and a dispense location of the rinsing material. A plenum region located between the dispense location of the cleaning material and the vacuum location is vented.

Abstract: Apparatus and methods for removing particle contaminants from a surface of a substrate includes coating a layer of a viscoelastic material on the surface. The viscoelastic material is coated as a thin film and exhibits substantial liquid-like characteristic. An external force is applied to a first area of the surface coated with the viscoelastic material such that a second area of the surface coated with the viscoelastic material is not substantially subjected to the applied force. The force is applied for a time duration that is shorter than a intrinsic time of the viscoelastic material so as to access solid-like characteristic of the viscoelastic material. The viscoelastic material exhibiting solid-like characteristic interacts at least partially with at least some of the particle contaminants present on the surface.

Abstract: A first application of a cleaning material is made to a surface of a substrate. The cleaning material includes one or more viscoelastic materials for entrapping contaminants present on the surface of the substrate. A first application of a rinsing fluid is made to the surface of the substrate so as to rinse the cleaning material from the surface of the substrate. The first application of the rinsing fluid is also performed to leave a residual thin film of the rinsing fluid on the surface of the substrate. A second application of the cleaning material is made to the surface of the substrate having the residual thin film of rinsing fluid present thereon. A second application of the rinsing fluid is then made to the surface of the substrate so as to rinse the cleaning material from the surface of the substrate.

Abstract: Methods for repairing a carbon depleted low-k material in a low-k dielectric film layer of a semiconductor wafer include providing a proximity head with a plurality of nozzles disposed on a surface of the proximity head. A repair chemistry having a hydrocarbon group is applied to a portion of the semiconductor wafer that includes carbon depleted low-k material, through the proximity head. The application is used to deliver carbon from the repair chemistry into the carbon depleted low-k material so as to cause replacement of a hydrogen ion within a hydroxyl group in the carbon depleted low-k material with carbon containing hydrocarbon group of the repair chemistry. The carbon containing hydrocarbon group forms a bond with suspended oxygen ion of the hydroxyl group thereby substantially repairing the low-k dielectric layer. The semiconductor wafer is then moved to expose other portions of the semiconductor wafer to the repair chemistry.

Abstract: A method and system for cleaning a surface of a substrate after an etching operation includes determining a plurality of process parameters associated with the surface of the substrate. The process parameters define characteristics related to the surface of the substrate such as characteristics of the substrate surface to be cleaned, contaminants to be removed, features formed on the substrate and chemicals used in the fabrication operations. A plurality of application chemistries are identified based on the process parameters. The plurality of application chemistries includes a first application chemistry as an emulsion having a first immiscible liquid combined with a second immiscible liquid and solid particles distributed within the first immiscible liquid.

Abstract: A carrier for supporting a substrate during processing by a meniscus fowled by upper and lower proximity heads is described. The carrier includes a frame having an opening sized for receiving a substrate and a plurality of support pins for supporting the substrate within the opening. The opening is slightly larger than the substrate such that a gap exists between the substrate and the opening. Means for reducing a size and frequency of entrance and/or exit marks on substrates is provided, the means aiding and encouraging liquid from the meniscus to evacuate the gap. A method for reducing the size and frequency of entrance and exit marks is also provided.

Abstract: A first application of a cleaning material is made to a surface of a substrate. The cleaning material includes one or more viscoelastic materials for entrapping contaminants present on the surface of the substrate. A first application of a rinsing fluid is made to the surface of the substrate so as to rinse the cleaning material from the surface of the substrate. The first application of the rinsing fluid is also performed to leave a residual thin film of the rinsing fluid on the surface of the substrate. A second application of the cleaning material is made to the surface of the substrate having the residual thin film of rinsing fluid present thereon. A second application of the rinsing fluid is then made to the surface of the substrate so as to rinse the cleaning material from the surface of the substrate.

Abstract: A first application of a cleaning material is made to a surface of a substrate. The cleaning material includes one or more viscoelastic materials for entrapping contaminants present on the surface of the substrate. A first application of a rinsing fluid is made to the surface of the substrate so as to rinse the cleaning material from the surface of the substrate. The first application of the rinsing fluid is also performed to leave a residual thin film of the rinsing fluid on the surface of the substrate. A second application of the cleaning material is made to the surface of the substrate having the residual thin film of rinsing fluid present thereon. A second application of the rinsing fluid is then made to the surface of the substrate so as to rinse the cleaning material from the surface of the substrate.

Abstract: An apparatus, system and method for removing a damaged material from a low-k dielectric film layer include identifying a control chemistry, the control chemistry configured to selectively remove the damaged material from the low-k dielectric film layer, the damaged material being in a region where a feature was formed through the low-k dielectric film layer; establishing a plurality of process parameters characterizing aspects of the damaged material to be removed and applying the control chemistry to the low-k dielectric film layer, the application of the control chemistry being defined based on the established process parameters of the damaged material, such that the damaged material is substantially removed from the areas around the feature and the areas around the feature are substantially defined by low-k characteristics of the low-k dielectric film layer.

Abstract: A method for processing a substrate includes etching a surface of the substrate using an etching chemistry in a plasma chamber, the etching configured to define one or more features on the surface of the substrate. The features have some etch polymer residues as a result of the etching. The etching is terminated. A dry flash chemistry is applied into the plasma chamber. The plasma chamber is powered for a period of time between about 5 seconds and about 10 seconds to perform a dry flash etch. During the dry flash etch, the chamber is set to a low pressure of between about 5 mTorr and about 40 mTorr. The dry flash etch acts to weaken adhesion of the etch polymer residues to the features. The substrate is moved from plasma chamber and into a wet clean chamber for cleaning which removes the etch polymer residues during fluid cleaning.

Abstract: A carrier for supporting a substrate during processing by a meniscus fowled by upper and lower proximity heads is described. The carrier includes a frame having an opening sized for receiving a substrate and a plurality of support pins for supporting the substrate within the opening. The opening is slightly larger than the substrate such that a gap exists between the substrate and the opening Means for reducing a size and frequency of entrance and/or exit marks on substrates is provided, the means aiding and encouraging liquid from the meniscus to evacuate the gap. A method for reducing the size and frequency of entrance and exit marks is also provided.

Abstract: A carrier for supporting a substrate during processing by a meniscus formed by upper and lower proximity heads is described. The carrier includes a frame having an opening sized for receiving a substrate and a plurality of support pins for supporting the substrate within the opening. The opening is slightly larger than the substrate such that a gap exists between the substrate and the opening. Means for reducing a size and frequency of entrance and/or exit marks on substrates is provided, the means aiding and encouraging liquid from the meniscus to evacuate the gap. A method for reducing the size and frequency of entrance and exit marks is also provided.

Abstract: An apparatus, system and method for preventing premature drying of a surface of a substrate between fabrication operations includes receiving a substrate for cleaning, performing wet cleaning operations to the surface of the substrate to remove contaminants and fabrication chemistries left behind during one or more fabrication operations from the surface of the substrate, identifying a saturated gas chemistry and applying the identified saturated gas chemistry in a transition region such that the surface of the substrate exposed to the saturated gas chemistry in the transition region retains the moisture thereby preventing the surface of the substrate from premature drying. The saturated gas chemistry is applied between two subsequent wet-cleaning operations.

Abstract: A carrier for supporting a substrate during processing by a meniscus formed by upper and lower proximity heads is described. The carrier includes a frame having an opening sized for receiving a substrate and a plurality of support pins for supporting the substrate within the opening. The opening is slightly larger than the substrate such that a gap exists between the substrate and the opening. Means for reducing a size and frequency of entrance and/or exit marks on substrates is provided, the means aiding and encouraging liquid from the meniscus to evacuate the gap. A method for reducing the size and frequency of entrance and exit marks is also provided.

Abstract: A system for processing a wafer with a low surface tension liquid includes a low surface tension liquid source including a first heat source capable of heating the low surface tension liquid to not more than 25 degrees C. less than boiling point of the low surface tension liquid, a delivery mechanism for delivering the heated low surface tension liquid to an air/liquid interface region and a second heat source directed toward the air/liquid interface region, the second heat source capable of heating the air/liquid interface region to at least 2 degrees C. greater than the boiling point of the low surface tension liquid. A method for processing a wafer with a low surface tension liquid is also described.

Abstract: A carrier for supporting a substrate during processing by a meniscus formed by upper and lower proximity heads is described. The carrier includes a frame having an opening sized for receiving a substrate and a plurality of support pins for supporting the substrate within the opening. The opening is slightly larger than the substrate such that a gap exists between the substrate and the opening. Means for reducing a size and frequency of entrance and/or exit marks on substrates is provided, the means aiding and encouraging liquid from the meniscus to evacuate the gap. A method for reducing the size and frequency of entrance and exit marks is also provided.

Abstract: Provided are methods for processing a substrate using a proximity system defined by one or more meniscus windows on one or more proximity heads. One method includes applying a first fluid meniscus to a surface of the substrate to apply a chemical precursor to the surface of the substrate. The first fluid meniscus is applied to first proximity meniscus window. Then, applying a second fluid meniscus to the surface of the substrate to leave an atomic layer of the chemical precursor on the surface of the substrate, through a second proximity meniscus window. A third fluid meniscus is applied to the surface of the substrate to apply a chemical reactant configured to react with the atomic layer of the chemical precursor to generate a layer of a material, through a third proximity meniscus window.