Abstract: An apparatus and method for processing a substrate in a processing system containing a deposition chamber, a treatment chamber, and an isolation region, separating the deposition chamber from the treatment is described herein. The deposition chamber deposits a film on a substrate. The treatment chamber receives the substrate from the deposition chamber and alters the film deposited in the deposition chamber with a film property altering device. Processing systems and methods are provided in accordance with the above embodiment and other embodiments.

Abstract: Embodiments described herein provide a method for sealing a porous low-k dielectric film. The method includes forming a sealing layer on the porous low-k dielectric film using a cyclic process. The cyclic process includes repeating a sequence of depositing a sealing layer on the porous low-k dielectric film and treating the sealing layer until the sealing layer achieves a predetermined thickness. The treating of each intermediate sealing layer generates more reactive sites on the surface of each intermediate sealing layer, which improves the quality of the resulting sealing layer.

Abstract: A low-k dielectric porous silicon oxycarbon layer is formed within an integrated circuit. In one embodiment, a porogen and bulk layer containing silicon oxycarbon layer is deposited, the porogens are selectively removed from the formed layer without simultaneously cross-linking the bulk layer, and then the bulk layer material is cross-linked. In other embodiments, multiple silicon oxycarbon sublayers are deposited, porogens from each sub-layer are selectively removed without simultaneously cross-linking the bulk material of the sub-layer, and the sub-layers are cross-linked separately.

Abstract: A method for sealing porous low-k dielectric films is provided. The method comprises exposing a substrate to UV radiation and a first reactive gas, wherein the substrate has an open feature defined therein, the open feature defined by a porous low-k dielectric layer and a conductive material, wherein the porous low-k dielectric layer is a silicon and carbon containing material and selectively forming a pore sealing layer in the open feature on exposed surfaces of the porous low-k dielectric layer using UV assisted photochemical vapor deposition.

Abstract: Embodiments described herein generally relate to methods for processing a dielectric film on a substrate with UV energy. In one embodiment, a precursor film is deposited on the substrate, and the precursor film includes a plurality of porogen molecules. The precursor film is first exposed to UV energy at a first temperature to initiate a cross-linking process. After a first predetermined time, the temperature of the precursor film is increased to a second temperature for a second predetermined time to remove porogen molecules and to continue the cross-linking process. The resulting film is a porous low-k dielectric film having improved elastic modulus and hardness.

Abstract: A method of forming features in a dielectric layer is described. A via, trench or a dual-damascene structure may be present in the dielectric layer prior to depositing a conformal aluminum nitride layer. The conformal aluminum nitride layer is configured to serve as a barrier to prevent diffusion across the barrier. The methods of forming the aluminum nitride layer involve the alternating exposure to two precursor treatments (like ALD) to achieve high conformality. The high conformality of the aluminum nitride barrier layer enables the thickness to be reduced and the effective conductivity of the subsequent gapfill metal layer to be increased.

Abstract: Implementations described herein generally relate to the formation of a silicon and aluminum containing layer. Methods described herein can include positioning a substrate in a process region of a process chamber; delivering a process gas to the process region, the process gas comprising an aluminum-containing gas and a silicon-containing gas; activating a reactant gas comprising a nitrogen-containing gas, a hydrogen containing gas, or combinations thereof; delivering the reactant gas to the process gas to create a deposition gas that deposits a silicon and aluminum containing layer on the substrate; and purging the process region. The above elements can be performed one or more times to deposit an etch stop stack.

Abstract: Embodiments described herein generally relate to the formation of a UV compatible barrier stack. Methods described herein can include delivering a process gas to a substrate positioned in a process chamber. The process gas can be activated to form an activated process gas, the activated process gas forming a barrier layer on a surface of the substrate, the barrier layer comprising silicon, carbon and nitrogen. The activated process gas can then be purged from the process chamber. An activated nitrogen-containing gas can be delivered to the barrier layer, the activated nitrogen-containing gas having a N2:NH3 ratio of greater than about 1:1. The activated nitrogen-containing gas can then be purged from the process chamber. The above elements can be performed one or more times to deposit the barrier stack.

Abstract: A method for sealing porous low-k dielectric films is provided. The method comprises exposing a substrate to UV radiation and a first reactive gas, wherein the substrate has an open feature defined therein, the open feature defined by a porous low-k dielectric layer and a conductive material, wherein the porous low-k dielectric layer is a silicon and carbon containing material and selectively forming a pore sealing layer in the open feature on exposed surfaces of the porous low-k dielectric layer using UV assisted photochemical vapor deposition.

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: Implementations described herein generally relate to methods for depositing etch stop layers, such as AlN layers, using UV assisted CVD. Methods disclosed herein generally include positioning a substrate in a process region of a process chamber; delivering an aluminum-containing precursor to the process region, the aluminum-containing precursor depositing an aluminum species onto the substrate; purging the process region of aluminum-containing precursor using an inert gas; delivering a UV responsive nitrogen-containing precursor to the process region, the UV responsive nitrogen-containing gas being activated using UV radiation to create nitrogen radicals, the nitrogen radicals reacting with the aluminum species to form an AlN layer; and purging the process region of UV responsive nitrogen-containing precursor using an inert gas.

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: A method of forming features in a dielectric layer is described. A via, trench or a dual-damascene structure may be present in the dielectric layer prior to depositing a conformal aluminum nitride layer. The conformal aluminum nitride layer is configured to serve as a barrier to prevent diffusion across the barrier. The methods of forming the aluminum nitride layer involve the alternating exposure to two precursor treatments (like ALD) to achieve high conformality. The high conformality of the aluminum nitride barrier layer enables the thickness to be reduced and the effective conductivity of the subsequent gapfill metal layer to be increased.

Abstract: Embodiments of the disclosure generally provide multi-layer dielectric stack configurations that are resistant to plasma damage. Methods are disclosed for the deposition of thin protective low dielectric constant layers upon bulk low dielectric constant layers to create the layer stack. As a result, the dielectric constant of the multi-layer stack is unchanged during and after plasma processing.

Abstract: A method of forming features in a low-k dielectric layer is described. A via, trench or a dual damascene structure may be present in the low-k dielectric layer prior to depositing a conformal hermetic layer. The conformal hermetic layer is configured to keep water and contaminants out. Some of the same conformal hermetic layer may deposit on the underlying copper. The portion of the conformal hermetic layer on the underlying copper is preferentially removed but the beneficial portion on the low-k dielectric layer remains. The selective removal of the conformal hermetic layer may be accomplished using a dry etch or a wet etch using a weak organic acid.

Abstract: Implementations described herein generally relate to methods for depositing etch stop layers, such as AlN layers, using UV assisted CVD. Methods disclosed herein generally include positioning a substrate in a process region of a process chamber; delivering an aluminum-containing precursor to the process region, the aluminum-containing precursor depositing an aluminum species onto the substrate; purging the process region of aluminum-containing precursor using an inert gas; delivering a UV responsive nitrogen-containing precursor to the process region, the UV responsive nitrogen-containing gas being activated using UV radiation to create nitrogen radicals, the nitrogen radicals reacting with the aluminum species to form an AlN layer; and purging the process region of UV responsive nitrogen-containing precursor using an inert gas.

Abstract: Implementations described herein generally relate to the formation of a silicon and aluminum containing layer. Methods described herein can include positioning a substrate in a process region of a process chamber; delivering a process gas to the process region, the process gas comprising an aluminum-containing gas and a silicon-containing gas; activating a reactant gas comprising a nitrogen-containing gas, a hydrogen containing gas, or combinations thereof; delivering the reactant gas to the process gas to create a deposition gas that deposits a silicon and aluminum containing layer on the substrate; and purging the process region. The above elements can be performed one or more times to deposit an etch stop stack.

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: An apparatus and method for processing a substrate in a processing system containing a deposition chamber, a treatment chamber, and an isolation region, separating the deposition chamber from the treatment is described herein. The deposition chamber deposits a film on a substrate. The treatment chamber receives the substrate from the deposition chamber and alters the film deposited in the deposition chamber with a film property altering device. Processing systems and methods are provided in accordance with the above embodiment and other embodiments.

Abstract: A method and apparatus for depositing a low K dielectric film with one or more features is disclosed herein. A method of forming a dielectric layer can include positioning a substrate in a processing chamber, delivering a deposition gas to the processing chamber, depositing a dense organosilicon layer using the deposition gas on the surface of the substrate, the dense organosilicon layer comprising a porogenic carbon, transferring a pattern into the dense organosilicon layer, forming a pore-forming plasma from a reactant gas, exposing the dense organosilicon layer to the pore-forming plasma to create a porous organosilicon layer, wherein the pore-forming plasma removes at least a portion of the porogenic carbon and exposing the porous organosilicon layer to a desiccating post treatment.