Abstract: Methods for detecting valve leakage and apparatus for the same are provided. In one embodiment, a method for detecting a valve leakage includes flowing a gas through a diverter valve, determining a pressure in a gas source provided to the diverter valve, comparing the determined pressure value with an expected pressure value, and generating a signal in response to the comparison.

Abstract: Embodiments of the invention provide methods for curing an ultra low-k dielectric film within a UV processing chamber. In one embodiment, the method includes depositing an ultra low-k dielectric layer on a substrate in a deposition chamber, and subjecting the deposited ultra low-k dielectric layer to a UV curing processes in a UV processing chamber. The method includes stabilizing the UV processing chamber by flowing an oxygen gas and a purge gas into the UV processing chamber at a flow ratio of about 1:50000 to about 1:100. While flowing the oxygen-doped purge gas, the substrate is exposed to UV radiation to cure the deposited ultra low-k dielectric layer. The inventive oxygen-doped purge curing process provides an alternate pathway to build silicon-oxygen network of the ultra low-k dielectric material, thereby accelerating cross-linking efficiency without significantly affecting the film properties of the deposited ultra low-k dielectric material.

Abstract: A method for cleaning a substrate processing chamber, including processing a batch of substrates within a processing chamber defining one or more processing regions. Processing the batch of substrates may be executed in a sub-routine having various sub-steps including processing a substrate from the batch within the processing chamber, removing the substrate from the processing chamber, introducing ozone into the processing chamber, and exposing the chamber to ultraviolet light for less than one minute. The substrate batch processing sub-steps may be repeated until the last substrate in the batch is processed. After processing the last substrate in the batch, the method includes removing the last substrate from the processing chamber, introducing ozone into the processing chamber; and exposing the processing chamber to ultraviolet light for three to fifteen minutes.

Abstract: The present invention provides systems, methods and apparatus for manufacturing a memory cell. The invention includes forming a feature having sidewalls in a first dielectric material; forming a first conductive material on the sidewalls of the feature; depositing a layer of a second dielectric material on the conductive material; and exposing the second dielectric material to oxidizing species and ultraviolet light to oxidize the second dielectric material. Numerous additional aspects are disclosed.

Abstract: A cleaning method for a UV chamber involves providing a first cleaning gas, a second cleaning gas, and a purge gas to one or more openings in the chamber. The first cleaning gas may be an oxygen containing gas, such as ozone, to remove carbon residues. The second cleaning gas may be a remote plasma of NF3 and O2 to remove silicon residues. The UV chamber may have two UV transparent showerheads, which together with a UV window in the chamber lid, define a gas volume proximate the UV window and a distribution volume below the gas volume. A purge gas may be flowed through the gas volume while one or more of the cleaning gases is flowed into the distribution volume to prevent the cleaning gases from impinging on the UV transparent window.

Abstract: Embodiments of the invention generally provide methods for cleaning a UV processing chamber. In one embodiment, the method includes flowing an oxygen-containing gas through a plurality of passages formed in a UV transparent gas distribution showerhead and into a processing region located between the UV transparent gas distribution showerhead and a substrate support disposed within the thermal processing chamber, exposing the oxygen-containing gas to UV radiation under a pressure scheme comprising a low pressure stage and a high pressure stage to generate reactive oxygen radicals, and removing unwanted residues or deposition build-up from exposed surfaces of chamber components presented in the thermal processing chamber using the reactive oxygen radicals.

Abstract: Embodiments of the present invention generally relate to methods for lowering the dielectric constant of low-k dielectric films used in semiconductor fabrication. In one embodiment, a method for lowering the dielectric constant (k) of a low-k silicon-containing dielectric film, comprising exposing a porous low-k silicon-containing dielectric film to a hydrofluoric acid solution and subsequently exposing the low-k silicon-containing dielectric film to a silylation agent. The silylation agent reacts with Si—OH functional groups in the porous low-k dielectric film to increase the concentration of carbon in the low-k dielectric film.

Abstract: A method for repairing and lowering the dielectric constant of low-k dielectric layers used in semiconductor fabrication is provided. In one implementation, a method of repairing a damaged low-k dielectric layer comprising exposing the porous low-k dielectric layer to a vinyl silane containing compound and optionally exposing the porous low-k dielectric layer to an ultraviolet (UV) cure process.

Abstract: Embodiments of the invention provide methods for curing an ultra low-k dielectric film within a UV processing chamber. In one embodiment, the method includes depositing an ultra low-k dielectric layer on a substrate in a deposition chamber, and subjecting the deposited ultra low-k dielectric layer to a UV curing processes in a UV processing chamber. The method includes stabilizing the UV processing chamber by flowing an oxygen gas and a purge gas into the UV processing chamber at a flow ratio of about 1:50000 to about 1:100. While flowing the oxygen-doped purge gas, the substrate is exposed to UV radiation to cure the deposited ultra low-k dielectric layer. The inventive oxygen-doped purge curing process provides an alternate pathway to build silicon-oxygen network of the ultra low-k dielectric material, thereby accelerating cross-linking efficiency without significantly affecting the film properties of the deposited ultra low-k dielectric material.

Abstract: Embodiments of the invention generally provide methods for cleaning a UV processing chamber. In one embodiment, the method includes flowing an oxygen-containing gas through a plurality of passages formed in a UV transparent gas distribution showerhead and into a processing region located between the UV transparent gas distribution showerhead and a substrate support disposed within the thermal processing chamber, exposing the oxygen-containing gas to UV radiation under a pressure scheme comprising a low pressure stage and a high pressure stage to generate reactive oxygen radicals, and removing unwanted residues or deposition build-up from exposed surfaces of chamber components presented in the thermal processing chamber using the reactive oxygen radicals.

Abstract: Methods for the repair of damaged low k films are provided. Damage to the low k films occurs during processing of the film such as during etching, ashing, and planarization. The processing of the low k film causes water to store in the pores of the film and further causes hydrophilic compounds to form in the low k film structure. Repair processes incorporating ultraviolet (UV) radiation and silylation compounds remove the water from the pores and further remove the hydrophilic compounds from the low k film structure.

Abstract: Methods for depositing a carbon-based seasoning layer on exposed surfaces of the optical components within a UV processing chamber are disclosed. In one embodiment, the method includes flowing a carbon-containing precursor radially inwardly across exposed surfaces of optical components within the thermal processing chamber from a circumference of the optical components, exposing the carbon-containing precursor to a thermal radiation emitted from a heating source to form a carbon-based seasoning layer on the exposed surfaces of the optical components, exposing the carbon-based seasoning layer to ozone, wherein the ozone is introduced into the processing chamber by flowing the ozone radially inwardly across exposed surfaces of optical components from the circumference of the optical components, heating the optical components to a temperature of about 400° C. or above while flowing the ozone to remove the carbon-based seasoning layer from exposed surfaces of the optical components.

Abstract: A method and apparatus for treating a substrate is provided. A porous dielectric layer is formed on the substrate. In some embodiments, the dielectric may be capped by a dense dielectric layer. The dielectric layers are patterned, and a dense dielectric layer deposited conformally over the substrate. The dense conformal dielectric layer seals the pores of the porous dielectric layer against contact with species that may infiltrate the pores. The portion of the dense conformal pore-sealing dielectric layer covering the field region and bottom portions of the pattern openings is removed by directional selective etch.

Abstract: A method and apparatus for providing a uniform UV radiation irradiance profile across a surface of a substrate is provided. In one embodiment, a substrate processing tool includes a processing chamber defining a processing region, a substrate support for supporting a substrate within the processing region, an ultraviolet (UV) radiation source spaced apart from the substrate support and configured to transmit ultraviolet radiation toward the substrate positioned on the substrate support, and a light transmissive window positioned between the UV radiation source and the substrate support, the light transmissive window having an optical film layer coated thereon. In one example, the optical film layer has a non-uniform thickness profile in a radial direction, wherein a thickness of the optical film layer at the peripheral area of the light transmissive window is relatively thicker than at the center region of the optical film layer.

Abstract: Methods are provided for forming a structure that includes an air gap. In one embodiment, a method is provided for forming a damascene structure including depositing a porous low dielectric constant layer by a method including reacting an organosilicon compound and a porogen-providing precursor, depositing a porogen-containing material, and removing at least a portion of the porogen-containing material, depositing an organic layer on the porous low dielectric constant layer by reacting the porogen-providing precursor, forming a feature definition in the organic layer and the porous low dielectric constant layer, filing the feature definition with a conductive material therein, depositing a mask layer on the organic layer and the conductive material disposed in the feature definition, forming apertures in the mask layer to expose the organic layer, removing a portion or all of the organic layer through the apertures, and forming an air gap adjacent the conductive material.

Abstract: Embodiments of the present invention pertain to the formation of microelectronic structures. Low k dielectric materials need to exhibit a dielectric constant of less than about 2.6 for the next technology node of 32 nm. The present invention enables the formation of semiconductor devices which make use of such low k dielectric materials while providing an improved flexural and shear strength integrity of the microelectronic structure as a whole.

Abstract: Methods for the repair of damaged low k films are provided. Damage to the low k films occurs during processing of the film such as during etching, ashing, and planarization. The processing of the low k film causes water to store in the pores of the film and further causes hydrophilic compounds to form in the low k film structure. Repair processes incorporating ultraviolet (UV) radiation and silylation compounds remove the water from the pores and further remove the hydrophilic compounds from the low k film structure.

Abstract: A method and apparatus for treating a substrate is provided. A porous dielectric layer is formed on the substrate. In some embodiments, the dielectric may be capped by a dense dielectric layer. The dielectric layers are patterned, and a dense dielectric layer deposited conformally over the substrate. The dense conformal dielectric layer seals the pores of the porous dielectric layer against contact with species that may infiltrate the pores. The portion of the dense conformal pore-sealing dielectric layer covering the field region and bottom portions of the pattern openings is removed by directional selective etch.

Abstract: A method and apparatus for treating a substrate is provided. A porous dielectric layer is formed on the substrate. In some embodiments, the dielectric may be capped by a dense dielectric layer. The dielectric layers are patterned, and a dense dielectric layer deposited conformally over the substrate. The dense conformal dielectric layer seals the pores of the porous dielectric layer against contact with species that may infiltrate the pores. The portion of the dense conformal pore-sealing dielectric layer covering the field region and bottom portions of the pattern openings is removed by directional selective etch.

Abstract: The present invention provides systems, methods and apparatus for manufacturing a memory cell. The invention includes forming a feature having sidewalls in a first dielectric material; forming a first conductive material on the sidewalls of the feature; depositing a layer of a second dielectric material on the conductive material; and exposing the second dielectric material to oxidizing species and ultraviolet light to oxidize the second dielectric material. Numerous additional aspects are disclosed.