Abstract: Embodiments of the invention relate to apparatuses and methods for depositing materials on substrates during atomic layer deposition processes. In one embodiment, a chamber for processing substrates is provided which includes a chamber lid assembly containing an expanding channel extending along a central axis at a central portion of the chamber lid assembly and a tapered bottom surface extending from the expanding channel to a peripheral portion of the chamber lid assembly. The tapered bottom surface may be shaped and sized to substantially cover the substrate receiving surface. The chamber lid assembly further contains a conduit coupled to a gas passageway, another conduit coupled to another gas passageway, and both gas passageways circumvent the expanding channel. Each of the passageways has a plurality of inlets extending into the expanding channel and the inlets are positioned to provide a circular gas flow through the expanding channel.

Abstract: Embodiments are related to ampoule assemblies containing bypass lines and valves. In one embodiment, ampoule assembly is provided which includes inlet and outlet lines coupled with and in fluid communication to an ampoule body, a bypass line connected between the inlet and outlet lines and containing a bypass valve disposed therein. The ampoule assembly further contains a shut-off valve disposed in the inlet line between the ampoule body and a connection point of the bypass line and the inlet line, a shut-off valve disposed in the outlet line between the ampoule body and a connection point of the bypass line and the outlet line, another shut-off valve disposed in the inlet line between the ampoule body and a disconnect fitting disposed on the inlet line, and another shut-off valve disposed in the outlet line between the ampoule body and a disconnect fitting disposed on the outlet line.

Abstract: Embodiments of the invention generally provide methods for depositing and compositions of tantalum carbide nitride materials. The methods include deposition processes that form predetermined compositions of the tantalum carbide nitride material by controlling the deposition temperature and the flow rate of a nitrogen-containing gas during a vapor deposition process, including thermal decomposition, CVD, pulsed-CVD, or ALD. In one embodiment, a method for forming a tantalum-containing material on a substrate is provided which includes heating the substrate to a temperature within a process chamber, and exposing the substrate to a nitrogen-containing gas and a process gas containing a tantalum precursor gas while depositing a tantalum carbide nitride material on the substrate.

Abstract: Embodiments of the invention provide a method for forming a material on a substrate during an atomic layer deposition (ALD) process, such as a plasma-enhanced ALD (PE-ALD) process. In one embodiment, a method is provided which includes flowing at least one process gas through at least one conduit to form a circular gas flow pattern, exposing a substrate to the circular gas flow pattern, sequentially pulsing at least one chemical precursor into the process gas and igniting a plasma from the process gas to deposit a material on the substrate. In one example, the circular gas flow pattern has circular geometry of a vortex, a helix, a spiral, or a derivative thereof. Materials that may be deposited by the method include ruthenium, tantalum, tantalum nitride, tungsten or tungsten nitride. Other embodiments of the invention provide an apparatus configured to form the material during the PE-ALD process.

Abstract: Embodiments of the invention generally provide compositions of tantalum carbide nitride materials. In one embodiment, a composition of a tantalum carbide nitride material is provided which includes the chemical formula of TaCxNy, wherein x is within a range from about 0.20 to about 0.50 and y is within a range from about 0.20 to about 0.55, an interstitial/elemental carbon atomic ratio of about 2 or greater, and a crystalline structure. In some examples, the composition provides that x is within a range from about 0.25 to about 0.40, preferably, from about 0.30 to about 0.40, and y is within a range from about 0.30 to about 0.50, preferably, from about 0.35 to about 0.50. The interstitial/elemental carbon atomic ratio may be about 3, about 4, or greater. The composition further may have a sheet resistance within a range from about 1×104 ?/sq to about 1×106 ?/sq.

Abstract: Embodiments described herein provide ampoule assemblies to contain, store, or dispense chemical precursors. In one embodiment, an ampoule assembly is provided which includes an ampoule containing a first material layer disposed on the outside of the ampoule and a second material layer disposed over the first material layer, wherein the first material layer is thermally more conductive than the second material layer, an inlet line in fluid communication with the ampoule and containing a first manual shut-off valve disposed therein, an outlet line in fluid communication with the ampoule and containing a second manual shut-off valve disposed therein, and a first bypass line connected between the inlet line and the outlet line. In some embodiments, the ampoule assembly may contain disconnect fittings. In other embodiments, the first bypass line has a shut-off valve disposed therein to fluidly couple or decouple the inlet line and the outlet line.

Abstract: Embodiments are related to ampoule assemblies containing bypass lines and valves. In one embodiment, ampoule assembly is provided which includes inlet and outlet lines coupled with and in fluid communication to an ampoule body, a bypass line connected between the inlet and outlet lines and containing a bypass valve disposed therein. The ampoule assembly further contains a shut-off valve disposed in the inlet line between the ampoule body and a connection point of the bypass line and the inlet line, a shut-off valve disposed in the outlet line between the ampoule body and a connection point of the bypass line and the outlet line, another shut-off valve disposed in the inlet line between the ampoule body and a disconnect fitting disposed on the inlet line, and another shut-off valve disposed in the outlet line between the ampoule body and a disconnect fitting disposed on the outlet line.

Abstract: Embodiments of the invention generally provide methods for depositing and compositions of tantalum carbide nitride materials. The methods include deposition processes that form predetermined compositions of the tantalum carbide nitride material by controlling the deposition temperature and the flow rate of a nitrogen-containing gas during a vapor deposition process, including thermal decomposition, CVD, pulsed-CVD, or ALD. In one embodiment, a method for forming a tantalum-containing material on a substrate is provided which includes heating the substrate to a temperature within a process chamber, and exposing the substrate to a nitrogen-containing gas and a process gas containing a tantalum precursor gas while depositing a tantalum carbide nitride material on the substrate.

Abstract: Embodiments described herein provide ampoule assemblies to contain, store, or dispense chemical precursors. In one embodiment, an ampoule assembly is provided which includes an ampoule containing a first material layer disposed on the outside of the ampoule and a second material layer disposed over the first material layer, wherein the first material layer is thermally more conductive than the second material layer, an inlet line in fluid communication with the ampoule and containing a first manual shut-off valve disposed therein, an outlet line in fluid communication with the ampoule and containing a second manual shut-off valve disposed therein, and a first bypass line connected between the inlet line and the outlet line. In some embodiments, the ampoule assembly may contain disconnect fittings. In other embodiments, the first bypass line has a shut-off valve disposed therein to fluidly couple or decouple the input line and the outlet line.

Abstract: An ampoule assembly is configured with a bypass line and valve to allow the purging of the lines and valves connected to the ampoule. The ampoule assembly, in one embodiment, includes an ampoule, an inlet line, an outlet line, and a bypass line connected between the inlet line and the outlet line, the bypass line having a shut-off valve disposed therein to fluidly couple or decouple the inlet line and the outlet line. The shut-off valve disposed in the bypass line may be remotely controllable. Also, additional remotely controllable shut-off valves may be provided in the inlet and the outlet lines.

Abstract: An atomic layer deposition chamber comprises a gas distributor comprising a central cap having a conical passageway between a gas inlet and gas outlet. The gas distributor also has a ceiling plate comprising first and second conical apertures that are connected. The first conical aperture receives a process gas from the gas outlet of the central cap. The second conical aperture extends radially outwardly from the first conical aperture. The gas distributor also has a peripheral ledge that rests on a sidewall of the chamber.

Abstract: Embodiments of the invention generally provide compositions of tantalum carbide nitride materials. In one embodiment, a composition of a tantalum carbide nitride material is provided which includes the chemical formula of TaCxNy, wherein x is within a range from about 0.20 to about 0.50 and y is within a range from about 0.20 to about 0.55, an interstitial/elemental carbon atomic ratio of about 2 or greater, and a crystalline structure. In some examples, the composition provides that x is within a range from about 0.25 to about 0.40, preferably, from about 0.30 to about 0.40, and y is within a range from about 0.30 to about 0.50, preferably, from about 0.35 to about 0.50. The interstitial/elemental carbon atomic ratio may be about 3, about 4, or greater. The composition further may have a sheet resistance within a range from about 1×104 ?/sq to about 1×106 ?/sq.

Abstract: Embodiments of the invention generally provide methods for depositing and compositions of tantalum carbide nitride materials. The methods include deposition processes that form predetermined compositions of the tantalum carbide nitride material by controlling the deposition temperature and the flow rate of a nitrogen-containing gas during a vapor deposition process, including thermal decomposition, CVD, pulsed-CVD, or ALD. In one embodiment, a method for forming a tantalum-containing material on a substrate is provided which includes heating the substrate to a temperature within a process chamber, and exposing the substrate to a nitrogen-containing gas and a process gas containing a tantalum precursor gas while depositing a tantalum carbide nitride material on the substrate.

Abstract: Embodiments of the invention provide an apparatus configured to form a material during an atomic layer deposition (ALD) process, such as a plasma-enhanced ALD (PE-ALD) process. In one embodiment, a plasma baffle assembly for receiving a process gas within a plasma-enhanced vapor deposition chamber is provided which includes a plasma baffle plate containing an upper surface to receive a process gas and a lower surface to emit the process gas, a plurality of openings configured to flow the process gas from above the upper surface to below the lower surface, wherein each opening is positioned at a predetermined angle of a vertical axis that is perpendicular to the lower surface, and a conical nose cone on the upper surface. In one example, the openings are slots positioned at a predetermined angle to emit the process gas with a circular flow pattern.

Abstract: Embodiments of the invention provide an apparatus and a process for generating a chemical precursor used in a vapor deposition processing system. The apparatus includes a canister (e.g., ampoule) having a sidewall, a top, and a bottom encompassing an interior volume therein, inlet and outlet ports in fluid communication with the interior volume, and a thermally conductive coating disposed on or over the outside surface of the canister. The thermally conductive coating is more thermally conductive than the outside surface of the canister. The thermally conductive coating may contain aluminum, aluminum nitride, copper, brass, silver, titanium, silicon nitride, or alloys thereof. In some embodiments, an adhesion layer (e.g., titanium or tantalum) may be disposed between the outside surface of the canister and the thermally conductive coating. In other embodiments, the canister may contain a plurality of baffles or solid heat-transfer particles to help evenly heat a solid precursor therein.