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 component. In one embodiment, a method for cleaning a UV processing chamber component includes soaking the chamber component having a SiCO residue formed thereon in a cleaning solution for about 1 to 10 minutes. The cleaning solution comprises about 5% by weight to about 60% weight of NH4F and about 0.5% by weight to about 10% by weight of HF. The method also includes polishing the chamber component. In another embodiment, a method of cleaning a processing chamber component fabricated from quartz includes soaking the chamber component having a SiCO residue formed thereon in a cleaning solution comprising about 36% by weight of NH4F and about by weight of HF for about 3 minutes. The method also includes applying an ultrasonic power to the cleaning solution, and mechanically polishing the chamber component.

Abstract: Embodiments described herein generally relate to preventing contaminant deposition within a semiconductor processing chamber and removing contaminants from a semiconductor processing chamber. Bottom purging and pumping prevents contaminant deposition below a pedestal heater or exhausts contaminants from below the pedestal, respectively. Bottom purging prevents contaminants from depositing below the pedestal and provides for an exhaust from the processing chamber to be located substantially coplanar with a substrate being processed. Bottom pumping removes contaminants present below the pedestal from the processing chamber. Specifically, embodiments described herein relate to purging and pumping via a pedestal bellows and/or equalization port.

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: 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 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: 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: Apparatus and methods for distributing gases into a processing chamber are disclosed. In one embodiment, the method for processing a substrate includes delivering a processing gas into a chemical vapor deposition chamber through a first gas pathway that includes flow through a first plurality of apertures in a blocker plate, the blocker plate creating a pressure drop of at least approximately 0.8 torr thereacross, reacting the processing gas to deposit a material on a substrate surface, removing the substrate from the chamber, delivering a cleaning gas into the chamber through a second gas pathway around the blocker plate bypassing the blocker plate and through a second plurality of apertures formed in the blocker plate, and reacting the cleaning gases with deposits within the chamber to etch the deposits from the chamber.

Abstract: Apparatus and methods for distributing gases into a processing chamber are disclosed. In one embodiment, the apparatus includes a gas distribution plate having a plurality of apertures disposed therethrough and a blocker plate having both a plurality of apertures disposed therethrough and a plurality of feed through passageways disposed therein. A first gas pathway delivers a first gas through the plurality of apertures in the blocker plate with sufficient pressure drop to more evenly distribute the gases prior to passing through the gas distribution plate. A bypass gas pathway delivers a second gas through the plurality of feed through passageways in the blocker plate and to areas around the blocker plate prior to the second gas passing through the gas distribution plate.

Abstract: Apparatus and methods for distributing gases into a processing chamber are disclosed. In one embodiment, the apparatus includes a gas distribution plate having a plurality of apertures disposed therethrough and a blocker plate having both a plurality of apertures disposed therethrough and a plurality of feed through passageways disposed therein. A first gas pathway delivers a first gas through the plurality of apertures in the blocker plate and the gas distribution plate. A bypass gas pathway delivers a second gas through the plurality of feed through passageways in the blocker plate and to areas around the blocker plate prior to the second gas passing through the gas distribution plate.

Abstract: Apparatus and methods for distributing gases into a processing chamber are disclosed. In one embodiment, the apparatus includes a gas distribution plate having a plurality of apertures disposed therethrough and a blocker plate having both a plurality of apertures disposed therethrough and a plurality of feed through passageways disposed therein. A first gas pathway delivers a first gas through the plurality of apertures in the blocker plate with sufficient pressure drop to more evenly distribute the gases prior to passing through the gas distribution plate. A bypass gas pathway delivers a second gas through the plurality of feed through passageways in the blocker plate and to areas around the blocker plate prior to the second gas passing through the gas distribution plate.

Abstract: A method of processing a substrate including depositing a low dielectric constant film comprising silicon, carbon, and oxygen on the substrate and depositing an oxide rich cap on the low dielectric constant film is provided. The low dielectric constant film is deposited in the presence of low frequency RF power from a gas mixture including an organosilicon compound and an oxidizing gas. The low frequency RF power is terminated after the deposition of the low dielectric constant film. The oxide rich cap is deposited on the low dielectric constant film in the absence of low frequency RF power from another gas mixture including the organosilicon compound and the oxidizing gas used to deposit the low dielectric constant film.

Abstract: A method of processing a substrate including depositing a transition layer and a dielectric layer on a substrate in a processing chamber are provided. The transition layer is deposited from a processing gas including an organosilicon compound and an oxidizing gas. The flow rate of the organosilicon compound is ramped up during the deposition of the transition layer such that the transition layer has a carbon concentration gradient and an oxygen concentration gradient. The transition layer improves the adhesion of the dielectric layer to an underlying barrier layer on the substrate.

Abstract: A method of processing a substrate including depositing a low dielectric constant film comprising silicon, carbon, and oxygen on the substrate and depositing an oxide rich cap on the low dielectric constant film is provided. The low dielectric constant film is deposited in the presence of low frequency RF power from a gas mixture including an organosilicon compound and an oxidizing gas. The low frequency RF power is terminated after the deposition of the low dielectric constant film. The oxide rich cap is deposited on the low dielectric constant film in the absence of low frequency RF power from another gas mixture including the organosilicon compound and the oxidizing gas used to deposit the low dielectric constant film.

Abstract: A method of processing a substrate including depositing a transition layer and a dielectric layer on a substrate in a processing chamber are provided. The transition layer is deposited from a processing gas including an organosilicon compound and an oxidizing gas. The flow rate of the organosilicon compound is ramped up during the deposition of the transition layer such that the transition layer has a carbon concentration gradient and an oxygen concentration gradient. The transition layer improves the adhesion of the dielectric layer to an underlying barrier layer on the substrate.

Abstract: A method and apparatus for cleaning a semiconductor manufacturing chamber comprising introducing a heteroatomic fluorine containing gas to a remote plasma source, disassociating the heteroatomic fluorine containing gas, forming diatomic fluorine, transporting gas from the remote plasma source into a processing region of the chamber, and ionizing the diatomic fluorine with an in situ plasma.

Abstract: Apparatus and methods for distributing gases into a processing chamber are disclosed. In one embodiment, the apparatus includes a gas distribution plate having a plurality of apertures disposed therethrough and a blocker plate having both a plurality of apertures disposed therethrough and a plurality of feed through passageways disposed therein. A first gas pathway delivers a first gas through the plurality of apertures in the blocker plate and the gas distribution plate. A bypass gas pathway delivers a second gas through the plurality of feed through passageways in the blocker plate and to areas around the blocker plate prior to the second gas passing through the gas distribution plate.

Abstract: Apparatus and methods for distributing gases into a processing chamber are disclosed. In one embodiment, the apparatus includes a gas distribution plate having a plurality of apertures disposed therethrough and a blocker plate having both a plurality of apertures disposed therethrough and a plurality of feed through passageways disposed therein. A first gas pathway delivers a first gas through the plurality of apertures in the blocker plate with sufficient pressure drop to more evenly distribute the gases prior to passing through the gas distribution plate. A bypass gas pathway delivers a second gas through the plurality of feed through passageways in the blocker plate and to areas around the blocker plate prior to the second gas passing through the gas distribution plate.