Abstract: A wafer is positioned on a wafer support apparatus beneath an electrode such that a plasma generation region exists between the wafer and the electrode. Radiofrequency power is supplied to the electrode to generate a plasma within the plasma generation region during multiple sequential plasma processing cycles of a plasma processing operation. At least one electrical sensor connected to the electrode measures a radiofrequency parameter on the electrode during each of the multiple sequential plasma processing cycles. A value of the radiofrequency parameter as measured on the electrode is determined for each of the multiple sequential plasma processing cycles. A determination is made as to whether or not any indicatory trend or change exists in the values of the radiofrequency parameter as measured on the electrode over the multiple sequential plasma processing cycles, where the indicatory trend or change indicates formation of a plasma instability during the plasma processing operation.

Abstract: A gas delivery system includes a first valve including an inlet that communicates with a first gas source. A first inlet of a second valve communicates with an outlet of the first valve and a second inlet of the second valve communicates with a second gas source. An inlet of a third valve communicates with a third gas source. A connector includes a first gas channel and a cylinder defining a second gas channel. The cylinder and the first gas channel collectively define a flow channel between an outer surface of the cylinder and an inner surface of the first gas channel. The flow channel communicates with the outlet of the third valve and the first end of the second gas channel. A third gas channel communicates with the second gas channel, with the outlet of the second valve and with a gas distribution device of a processing chamber.

Abstract: A chemical deposition apparatus having a chemical deposition chamber formed within the chemical isolation chamber includes a gas seal. The chemical deposition chamber includes a showerhead module having a faceplate with gas inlets to deliver reactor chemistries to a wafer cavity for processing a semiconductor substrate. The showerhead module includes primary exhaust gas outlets to remove reaction gas chemistries and inert gases from the wafer cavity. An inert gas feed delivers seal gas which flows radially inwardly at least partly through a gap between a step of the showerhead module and the pedestal module to form a gas seal. Secondary exhaust gas outlets withdraw at least some of the inert gas flowing through the gap to provide a high Peclet number.

Abstract: A substrate processing system includes a processing chamber including a top surface, a bottom surface and side walls. A substrate support is arranged in the processing chamber to support a substrate during processing. A purge structure is arranged in the processing chamber below a plane occupied by the substrate during processing. The purge structure includes a first plurality of holes configured to supply purge gas to purge an area between the substrate support and the bottom surface of the processing chamber.

Abstract: A multi-station chamber having a symmetric ground plate is disclosed. The multi-station chamber includes four stations, and the four stations are arranged in a square configuration with a rotating mechanism in a center location. A pedestal for supporting a substrate is provided for each of the four stations, each pedestal is disposed in a lower chamber body, and each pedestal includes a carrier ring. The lower chamber body includes outer walls and inner walls to define a space for each of the pedestals of the four chambers. A ground plate is disposed over the inner walls and attached to the outer walls. The ground plate has a center opening and a process opening for each station. The center opening is configured to receive the rotating mechanism at the center location. The process opening has a diameter that is larger than a diameter of the carrier ring at each station, and a symmetric gap is defined between an edge of each process opening defined by the ground plate and an outer edge of a carrier ring.

Abstract: A gas delivery system includes a first valve including an inlet that communicates with a first gas source. A first inlet of a second valve communicates with an outlet of the first valve and a second inlet of the second valve communicates with a second gas source. An inlet of a third valve communicates with a third gas source. A connector includes a first gas channel and a cylinder defining a second gas channel. The cylinder and the first gas channel collectively define a flow channel between an outer surface of the cylinder and an inner surface of the first gas channel. The flow channel communicates with the outlet of the third valve and the first end of the second gas channel. A third gas channel communicates with the second gas channel, with the outlet of the second valve and with a gas distribution device of a processing chamber.

Abstract: A chemical deposition apparatus having conductance control, which includes a showerhead module having a faceplate and a backing plate, the showerhead module including a plurality of inlets which deliver reactor chemistries to a cavity and exhaust outlets which remove reactor chemistries, a pedestal module configured to support a substrate and which moves vertically to close the cavity between the pedestal module and an outer portion of the faceplate, and at least one conductance control assembly, which is in fluid communication with the cavity via the exhaust outlets. The at least one conductance control assembly selected from one or more of the following: a ball valve assembly, a fluidic valve, magnetically coupled rotary plates, and/or a linear based magnetic system.

Abstract: A showerhead in a semiconductor processing apparatus can include faceplate through-holes configured to improve the flow uniformity during atomic layer deposition. The showerhead can include a faceplate having a plurality of through-holes for distributing gas onto a substrate, where the faceplate includes small diameter through-holes. For example, the diameter of each of the through-holes can be less than about 0.04 inches. In addition or in the alternative, the showerhead can include edge through-holes positioned circumferentially along a ring having a diameter greater than a diameter of the substrate being processed. The showerhead can be a low volume showerhead and can include a baffle proximate one or more gas inlets in communication with a plenum volume of the showerhead. The faceplate with small diameter through-holes and/or edge through-holes can improve overall film non-uniformity, improve azimuthal film non-uniformity at the edge of the substrate, and enable operation at higher RF powers.

Abstract: A chemical deposition apparatus having conductance control, which includes a showerhead module having a faceplate and a backing plate, the showerhead module including a plurality of inlets which deliver reactor chemistries to a cavity and exhaust outlets which remove reactor chemistries, a pedestal module configured to support a substrate and which moves vertically to close the cavity between the pedestal module and an outer portion of the faceplate, and at least one conductance control assembly, which is in fluid communication with the cavity via the exhaust outlets. The at least one conductance control assembly selected from one or more of the following: a ball valve assembly, a fluidic valve, magnetically coupled rotary plates, and/or a linear based magnetic system.

Abstract: A substrate processing system includes a showerhead that comprises a base portion and a stem portion and that delivers precursor gas to a chamber. A collar connects the showerhead to an upper surface of the chamber. The collar includes a plurality of slots, is arranged around the stem portion of the showerhead, and directs purge gas through the plurality of slots into a region between the base portion of the showerhead and the upper surface of the chamber.

Abstract: A substrate processing system includes a showerhead that comprises a base portion and a stem portion and that delivers precursor gas to a chamber. A collar connects the showerhead to an upper surface of the chamber. The collar includes a plurality of slots, is arranged around the stem portion of the showerhead, and directs purge gas through the plurality of slots into a region between the base portion of the showerhead and the upper surface of the chamber.

Abstract: A system for supplying vaporized precursor includes an enclosure including an output. A plurality of trays is arranged in a stacked, spaced configuration inside the enclosure. The plurality of trays is configured to hold liquid precursor. A first conduit fluidly connects a carrier gas supply to the enclosure and includes a plurality of openings. A first valve is arranged along the first conduit and is configured to selectively control delivery of the carrier gas from the carrier gas supply through the first conduit to the plurality of openings in the first conduit. The plurality of openings is configured to direct the carrier gas across the liquid precursor in the plurality of trays, respectively. The output of the enclosure provides a mixture of the carrier gas and the vaporized precursor.

Abstract: Disclosed are methods of depositing films of material on semiconductor substrates. The methods may include flowing a film precursor into a processing chamber through a showerhead substantially maintained at a first temperature, and adsorbing the film precursor onto a substrate held on a substrate holder such that the precursor forms an adsorption-limited layer while the substrate holder is substantially maintained at a second temperature. The first temperature may be at least about 10° C. above the second temperature, or the first temperature may be at or below the second temperature. The methods may further include removing at least some unadsorbed film precursor from the volume surrounding the adsorbed film precursor, and thereafter reacting adsorbed film precursor to form a film layer. Also disclosed herein are apparatuses having a processing chamber, a substrate holder, a showerhead, and one or more controllers for operating the apparatus to employ the foregoing film deposition techniques.

Abstract: Methods and apparatus for use of a fill on demand ampoule are disclosed. The fill on demand ampoule may refill an ampoule with precursor concurrent with the performance of other deposition processes. The fill on demand may keep the level of precursor within the ampoule at a relatively constant level. The level may be calculated to result in an optimum head volume. The fill on demand may also keep the precursor at a temperature near that of an optimum precursor temperature. The fill on demand may occur during parts of the deposition process where the agitation of the precursor due to the filling of the ampoule with the precursor minimally effects the substrate deposition. Substrate throughput may be increased through the use of fill on demand.

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: Disclosed herein are methods of depositing layers of material on multiple semiconductor substrates at multiple processing stations within one or more reaction chambers. The methods may include dosing a first substrate with film precursor at a first processing station and dosing a second substrate with film precursor at a second processing station with precursor flowing from a common source, wherein the timing of said dosing is staggered such that the first substrate is dosed during a first dosing phase during which the second substrate is not substantially dosed, and the second substrate is dosed during a second dosing phase during which the first substrate is not substantially dosed. Also disclosed herein are apparatuses having a plurality of processing stations contained within one or more reaction chambers and a controller with machine-readable instructions for staggering the dosing of first and second substrates at first and second processing stations.

Abstract: Methods of depositing a film on a substrate surface include surface mediated reactions in which a film is grown over one or more cycles of reactant adsorption and reaction. In one aspect, the method is characterized by the following operations: (a) exposing the substrate surface to a first reactant in vapor phase under conditions allowing the first reactant to adsorb onto the substrate surface; (b) exposing the substrate surface to a second reactant in vapor phase while the first reactant is adsorbed on the substrate surface; and (c) exposing the substrate surface to plasma to drive a reaction between the first and second reactants adsorbed on the substrate surface to form the film.

Abstract: A low volume showerhead in a semiconductor processing apparatus can include a porous baffle to improve the flow uniformity and purge time during atomic layer deposition. The showerhead can include a plenum volume, one or more gas inlets in fluid communication with the plenum volume, a faceplate including a plurality of first through-holes for distributing gas onto a substrate in the semiconductor processing apparatus, and a porous baffle positioned in a region between the plenum volume and the one or more gas inlets. The one or more gas inlets can include a stem having a small volume to improve purge time. The baffle can be porous and positioned between the stem and the plenum volume to improve flow uniformity and avoid jetting.

Abstract: A system for supplying vaporized precursor includes an enclosure including an output. A plurality of trays is arranged in a stacked, spaced configuration inside the enclosure. The plurality of trays is configured to hold liquid precursor. A first conduit fluidly connects a carrier gas supply to the enclosure and includes a plurality of openings. A first valve is arranged along the first conduit and is configured to selectively control delivery of the carrier gas from the carrier gas supply through the first conduit to the plurality of openings in the first conduit. The plurality of openings is configured to direct the carrier gas across the liquid precursor in the plurality of trays, respectively. The output of the enclosure provides a mixture of the carrier gas and the vaporized precursor.

Abstract: Disclosed herein are methods of depositing layers of material on multiple semiconductor substrates at multiple processing stations within one or more reaction chambers. The methods may include dosing a first substrate with film precursor at a first processing station and dosing a second substrate with film precursor at a second processing station with precursor flowing from a common source, wherein the timing of said dosing is staggered such that the first substrate is dosed during a first dosing phase during which the second substrate is not substantially dosed, and the second substrate is dosed during a second dosing phase during which the first substrate is not substantially dosed. Also disclosed herein are apparatuses having a plurality of processing stations contained within one or more reaction chambers and a controller with machine-readable instructions for staggering the dosing of first and second substrates at first and second processing stations.