Abstract: Methods and apparatuses for controlling precursor flow in a semiconductor processing tool are disclosed. A method may include flowing gas through a gas line, opening an ampoule valve(s), before a dose step, to start a flow of precursor from the ampoule to a process chamber through the gas line, closing the ampoule valve(s) to stop the precursor from flowing out of the ampoule, opening a process chamber valve, at the beginning of the dose step, to allow the flow of precursor to enter the process chamber, and closing the process chamber valve, at the end of the dose step, to stop the flow of precursor from entering the process chamber. A controller may include at least one memory and at least one processor and the at least one memory may store instructions for controlling the at least one processor to control precursor flow in a semiconductor processing tool.

Abstract: The present inventors have conceived of a multi-stage process gas delivery system for use in a substrate processing apparatus. In certain implementations, a first process gas may first be delivered to a substrate in a substrate processing chamber. A second process gas may be delivered, at a later time, to the substrate to aid in the even dosing of the substrate. Delivery of the first process gas and the second process gas may cease at the same time or may cease at separate times.

Abstract: Methods and apparatuses for controlling precursor flow in a semiconductor processing tool are disclosed. A method may include flowing gas through a gas line, opening an ampoule valve(s), before a dose step, to start a flow of precursor from the ampoule to a process chamber through the gas line, closing the ampoule valve(s) to stop the precursor from flowing out of the ampoule, opening a process chamber valve, at the beginning of the dose step, to allow the flow of precursor to enter the process chamber, and closing the process chamber valve, at the end of the dose step, to stop the flow of precursor from entering the process chamber. A controller may include at least one memory and at least one processor and the at least one memory may store instructions for controlling the at least one processor to control precursor flow in a semiconductor processing tool.

Abstract: Methods and apparatus to form films on sensitive substrates while preventing damage to the sensitive substrate are provided herein. In certain embodiments, methods involve forming a bilayer film on a sensitive substrate that both protects the underlying substrate from damage and possesses desired electrical properties. Also provided are methods and apparatus for evaluating and optimizing the films, including methods to evaluate the amount of substrate damage resulting from a particular deposition process and methods to determine the minimum thickness of a protective layer. The methods and apparatus described herein may be used to deposit films on a variety of sensitive materials such as silicon, cobalt, germanium-antimony-tellerium, silicon-germanium, silicon nitride, silicon carbide, tungsten, titanium, tantalum, chromium, nickel, palladium, ruthenium, or silicon oxide.

Abstract: Methods and apparatus to form films on sensitive substrates while preventing damage to the sensitive substrate are provided herein. In certain embodiments, methods involve forming a bilayer film on a sensitive substrate that both protects the underlying substrate from damage and possesses desired electrical properties. Also provided are methods and apparatus for evaluating and optimizing the films, including methods to evaluate the amount of substrate damage resulting from a particular deposition process and methods to determine the minimum thickness of a protective layer. The methods and apparatus described herein may be used to deposit films on a variety of sensitive materials such as silicon, cobalt, germanium-antimony-tellerium, silicon-germanium, silicon nitride, silicon carbide, tungsten, titanium, tantalum, chromium, nickel, palladium, ruthenium, or silicon oxide.

Abstract: A vapor delivery system includes an ampoule to store liquid precursor and a heater to partially vaporize the liquid precursor. A first valve communicates with a push gas source and the ampoule. A second valve supplies vaporized precursor to a heated injection manifold. A valve manifold includes a first node in fluid communication with an outlet of the heated injection manifold, a third valve having an inlet in fluid communication with the first node and an outlet in fluid communication with vacuum, a fourth valve having an inlet in fluid communication with the first node and an outlet in fluid communication with a second node, a fifth valve having an outlet in fluid communication with the second node, and a sixth valve having an outlet in fluid communication with the second node. A gas distribution device is in fluid communication with the second node.

Abstract: Systems and methods for depositing film in a substrate processing system includes performing a first atomic layer deposition (ALD) cycle in a processing chamber to deposit film on a substrate including a feature; after the first ALD cycle, exposing the substrate to an inhibitor plasma in the processing chamber for a predetermined period to create a varying passivated surface in the feature; and after the predetermined period, performing a second ALD cycle in the processing chamber to deposit film on the substrate.

Abstract: A substrate processing system for depositing film on a substrate includes a processing chamber defining a reaction volume. A showerhead includes a stem portion having one end connected adjacent to an upper surface of the processing chamber. A base portion is connected to an opposite end of the stem portion and extends radially outwardly from the stem portion. The showerhead is configured to introduce at least one of process gas and purge gas into the reaction volume. A plasma generator is configured to selectively generate RF plasma in the reaction volume. An edge tuning system includes a collar and a parasitic plasma reducing element that is located around the stem portion between the collar and an upper surface of the showerhead. The parasitic plasma reducing element is configured to reduce parasitic plasma between the showerhead and the upper surface of the processing chamber.

Abstract: Systems and methods for operating a substrate processing system include processing a substrate arranged on a substrate support in a processing chamber. At least one of precursor gas and/or reactive gas is supplied during the processing. The substrate is removed from the processing chamber. Carrier gas and purge gas are selectively supplied to the processing chamber. RF plasma is generated in the processing chamber during N cycles, where N is an integer greater than one. The RF plasma is on for a first period and off for a second period during each of the N cycles. The purge gas is supplied during at least part of each of the N cycles.

Abstract: A process tuning kit for use in a chemical deposition apparatus wherein the process tuning kit includes a carrier ring, horseshoes and shims. The horseshoes have the same dimensions and the shims are provided in sets with different thicknesses to control the height of the horseshoes with respect to an upper surface of a pedestal assembly on which the horseshoes and shims are mounted. A semiconductor substrate is transported into a vacuum chamber of the chemical deposition apparatus by the carrier ring which is placed on the horseshoes such that minimum contact area supports lift the substrate from the carrier ring and support the substrate at a predetermined offset with respect to an upper surface of the pedestal assembly. During processing of the substrate, backside deposition can be reduced by using shims of desired thickness to control the predetermined offset.

Abstract: Disclosed are methods of depositing films of material on multiple semiconductor substrates in a multi-station processing chamber. The methods may include loading a first set of one or more substrates into the processing chamber at a first set of one or more process stations and depositing film material onto the first set of substrates by performing N cycles of film deposition. Thereafter, the methods may further include transferring the first set of substrates from the first set of process stations to a second set of one or more process stations, loading a second set of one or more substrates at the first set of process stations, and depositing film material onto the first and second sets of substrates by performing N? cycles of film deposition, wherein N? is not equal to N. Also disclosed are apparatuses and computer-readable media which may be used to perform similar operations.

Abstract: Methods and apparatuses for controlling precursor flow in a semiconductor processing tool are disclosed. A method may include flowing gas through a gas line, opening an ampoule valve(s), before a dose step, to start a flow of precursor from the ampoule to a process chamber through the gas line, closing the ampoule valve(s) to stop the precursor from flowing out of the ampoule, opening a process chamber valve, at the beginning of the dose step, to allow the flow of precursor to enter the process chamber, and closing the process chamber valve, at the end of the dose step, to stop the flow of precursor from entering the process chamber. A controller may include at least one memory and at least one processor and the at least one memory may store instructions for controlling the at least one processor to control precursor flow in a semiconductor processing tool.

Abstract: A method for processing a substrate in a substrate processing system includes flowing reactant gases into a process chamber including a substrate, supplying a first power level sufficient to promote rearrangement of molecules on a surface of the substrate, waiting a first predetermined period, and, after the first predetermined period, performing plasma-enhanced, pulsed chemical vapor deposition of film on the substrate by supplying one or more precursors while supplying a second power level for a second predetermined period. The second power level is greater than the first power level. The method further includes removing reactants from the process chamber.

Abstract: Provided herein are methods and apparatus for filling one or more gaps on a semiconductor substrate. The disclosed embodiments are especially useful for forming seam-free, void-free fill in both narrow and wide features. The methods may be performed without any intervening etching operations to achieve a single step deposition. In various implementations, a first operation is performed using a novel PEALD fill mechanism to fill narrow gaps and line wide gaps. A second operation may be performed using PECVD methods to continue filling the wide gaps.

Abstract: Methods and apparatus disclosed herein relate to the formation and use of undercoats on the interior surfaces of reaction chambers used to deposit films on substrates. The undercoats are deposited through atomic layer deposition methods. The disclosed undercoats help prevent metal contamination, provide improved resistance to flaking, and are relatively thin. Because of the superior resistance to flaking, the disclosed undercoats allow more substrates to be processed between subsequent cleaning operations, thereby increasing throughput.

Abstract: Methods and apparatus to form films on sensitive substrates while preventing damage to the sensitive substrate are provided herein. In certain embodiments, methods involve forming a bilayer film on a sensitive substrate that both protects the underlying substrate from damage and possesses desired electrical properties. Also provided are methods and apparatus for evaluating and optimizing the films, including methods to evaluate the amount of substrate damage resulting from a particular deposition process and methods to determine the minimum thickness of a protective layer. The methods and apparatus described herein may be used to deposit films on a variety of sensitive materials such as silicon, cobalt, germanium-antimony-tellerium, silicon-germanium, silicon nitride, silicon carbide, tungsten, titanium, tantalum, chromium, nickel, palladium, ruthenium, or silicon oxide.

Abstract: Disclosed are methods of depositing films of material on multiple semiconductor substrates in a multi-station processing chamber. The methods may include loading a first set of one or more substrates into the processing chamber at a first set of one or more process stations and depositing film material onto the first set of substrates by performing N cycles of film deposition. Thereafter, the methods may further include transferring the first set of substrates from the first set of process stations to a second set of one or more process stations, loading a second set of one or more substrates at the first set of process stations, and depositing film material onto the first and second sets of substrates by performing N? cycles of film deposition, wherein N? is not equal to N. Also disclosed are apparatuses and computer-readable media which may be used to perform similar operations.

Abstract: A substrate processing system for depositing film on a substrate includes a processing chamber defining a reaction volume. A showerhead includes a stem portion having one end connected adjacent to an upper surface of the processing chamber. A base portion is connected to an opposite end of the stem portion and extends radially outwardly from the stem portion. The showerhead is configured to introduce at least one of process gas and purge gas into the reaction volume. A plasma generator is configured to selectively generate RF plasma in the reaction volume. An edge tuning system includes a collar and a parasitic plasma reducing element that is located around the stem portion between the collar and an upper surface of the showerhead. The parasitic plasma reducing element is configured to reduce parasitic plasma between the showerhead and the upper surface of the processing chamber.

Abstract: Provided herein are methods and apparatus for filling one or more gaps on a semiconductor substrate. The disclosed embodiments are especially useful for forming seam-free, void-free fill in both narrow and wide features. The methods may be performed without any intervening etching operations to achieve a single step deposition. In various implementations, a first operation is performed using a novel PEALD fill mechanism to fill narrow gaps and line wide gaps. A second operation may be performed using PECVD methods to continue filling the wide gaps.

Abstract: Methods and apparatus to form films on sensitive substrates while preventing damage to the sensitive substrate are provided herein. In certain embodiments, methods involve forming a bilayer film on a sensitive substrate that both protects the underlying substrate from damage and possesses desired electrical properties. Also provided are methods and apparatus for evaluating and optimizing the films, including methods to evaluate the amount of substrate damage resulting from a particular deposition process and methods to determine the minimum thickness of a protective layer. The methods and apparatus described herein may be used to deposit films on a variety of sensitive materials such as silicon, cobalt, germanium-antimony-tellerium, silicon-germanium, silicon nitride, silicon carbide, tungsten, titanium, tantalum, chromium, nickel, palladium, ruthenium, or silicon oxide.