A film forming apparatus according to an embodiment includes: a film forming chamber configured to house therein a substrate to perform film forming processing; a gas supplier located in an upper part of the film forming chamber and configured to supply a process gas onto the substrate; and a heater configured to heat the substrate, wherein the film forming chamber has a temperature-increase suppression region being a lower part of the gas supplier and suppressing a temperature increase of the gas supplied to an upper part of the heater.

A plasma processing apparatus includes a plasma generation chamber in which plasma active species are generated, a process chamber configured to accommodate processing target objects stacked in a vertical direction, the plasma active species generated in the plasma generation chamber being supplied into the process chamber, a plasma source gas supply pipe disposed inside the plasma generation chamber and extending in the vertical direction, a plasma source gas being introduced from one end of the plasma source gas supply pipe and discharged through gas discharge holes formed in the plasma source gas supply pipe in the vertical direction, and a pair of plasma electrodes, arranged to face each other, configured to apply an electric field to the plasma source gas discharged into the plasma generation chamber. A size of a discharge area interposed between the pair of plasma electrodes is varied in the vertical direction.

The invention relates to method including operating a plasma atomic layer deposition reactor configured to deposit material in a reaction chamber on at least one substrate by sequential self-saturating surface reactions, and allowing gas from an inactive gas source to flow into a widening radical in-feed part opening towards the reaction chamber substantially during a whole deposition cycle. The invention also relates to a corresponding apparatus.

Embodiments described herein generally relate to a processing system and a method of delivering a reactant gas. The processing system includes a substrate support system, an injection cone, and an intake. The injection cone includes a linear rudder. The linear rudder is disposed such that the flow of reactant gas through the injection cone results in film growth on a specific portion of a substrate. The method includes flowing the gas through the injection cone and delivering the gas onto the substrate below. The localization of the reactant gas, allows for film growth on a specific portion of the substrate.

A vortical atomizing nozzle assembly, vaporizer, and related methods are disclosed for substrate processing systems. The vaporizer introduces an atomized or vaporized liquid into a substrate processing system and includes a vaporizer chamber, a nozzle assembly coupled to the inlet for the vaporizer chamber, and a carrier gas channel coupled to the nozzle assembly. The nozzle assembly includes a premix chamber, an outlet channel, and an expanding nozzle. The premix chamber includes a liquid inlet to receive the liquid to be vaporized and a gas inlet to receive the carrier gas. The carrier gas channel is positioned with respect to the gas inlet to cause a vortical flow within the premix chamber upon introduction of the carrier gas through the carrier gas channel. The premixed liquid from the premix chamber is received by the outlet channel and exits the outlet channel into the expanding nozzle.

The invention relates to method including operating a plasma atomic layer deposition reactor configured to deposit material in a reaction chamber on at least one substrate by sequential self-saturating surface reactions, and allowing gas from an inactive gas source to flow into a widening radical in-feed part opening towards the reaction chamber substantially during a whole deposition cycle. The invention also relates to a corresponding apparatus.

The current disclosure relates to example method, system and apparatus for coupling a delivery vessel disposed at a first location on a substrate processing platform to a remote refill vessel disposed in a second location remote from the substrate processing platform via a first chemical delivery line, storing a chemical in the remote refill vessel in a first phase, changing the chemical in the remote refill vessel to a second phase, transporting the chemical in the second phase, to the delivery vessel via the first chemical delivery line, heating the first chemical delivery line to a first temperature equal to or above a phase change temperature of the chemical, and coupling the delivery vessel to an accumulator via a second chemical delivery line.

Embodiments disclosed herein generally relate to a gas distribution assembly for providing improved uniform distribution of processing gases into a semiconductor processing chamber. The gas distribution assembly includes a gas distribution plate, a blocker plate, and a dual zone showerhead. The gas distribution assembly provides for independent center to edge flow zonality, independent two precursor delivery, two precursor mixing via a mixing manifold, and recursive mass flow distribution in the gas distribution plate.

Disclosed are methods of depositing films of material on semiconductor substrates employing the use of a secondary purge. The methods may include flowing a film precursor into a processing chamber and adsorbing the film precursor onto a substrate in the processing chamber such that the precursor forms an adsorption-limited layer on the substrate. The methods may further include removing at least some unadsorbed film precursor from the volume surrounding the adsorbed precursor by purging the processing chamber with a primary purge gas, and thereafter reacting adsorbed film precursor while a secondary purge gas is flowed into the processing chamber, resulting in the formation of a film layer on the substrate. The secondary purge gas may include a chemical species having an ionization energy and/or a disassociation energy equal to or greater than that of O.sub.2. Also disclosed are apparatuses which implement the foregoing processes.

A substrate processing apparatus includes a substrate support part provided with a first heating part, configured to heat a substrate, a gas supply part installed above the substrate support part and configured to supply a process gas to the substrate, a first exhaust port configured to exhaust an atmosphere of a process space existing above the substrate support part, a gas distribution part installed to face the substrate support part, a lid part provided with a second exhaust port configured to exhaust a buffer space existing between the gas supply part, and the gas distribution part, a rectifying part installed within the buffer space and provided with a second heating part at least partially facing the second exhaust port, the rectifying part configured to rectify the process gas, and a control part configured to control the second heating part.