A substrate processing apparatus for preventing adhesion of by-products to an inner surface of a furnace opening is disclosed. An apparatus is provided with: a process chamber, a substrate holder, a process gas supplier that supplies a process gas into the process chamber, a first heater that is installed outside the process chamber and heats an inside of the process chamber, a heat insulator that is installed between a lid of the process chamber and the substrate holder, a second heater that is installed near the substrate holder in the heat insulator and heats the inside of the process chamber, a third heater that is installed near an end closer to the lid in the process chamber and heats the end, and a supplier that supplies a purge gas to purge around the second and third heaters into the heat insulator.

A film-forming device that includes a cylindrical chamber capable of maintaining vacuum therein, a workpiece holder that is constructed to align and hold workpieces to be processed in multiple stages such that main surfaces of the workpieces are oriented in a vertical direction relative to a central axis of the chamber, a deposition material supply pipe, a modifier supply pipe, a carrier gas supply pipe, and an exhaust mechanism, wherein in a cross section of the chamber in a direction parallel to the main surfaces of the workpieces, the exhaust mechanism is located on a side opposite to an opening direction of gas outlets of the deposition, modifier, and carrier gas supply pipes, and a total gas flow from the deposition, modifier, and carrier gas supply pipes is symmetric about a centerline of the chamber.

A vaporization system includes a vaporization chamber having a first portion and a second portion. A first fluid supply part is connected to the first portion of the vaporization chamber, and configured to supply a mixed fluid in which a first carrier gas and a liquid precursor are mixed, toward the second portion. A second fluid supply part is configured to supply a second carrier gas toward the mixed fluid at the second portion.

A vaporization system includes a vaporization chamber having a first portion and a second portion. A first fluid supply part is connected to the first portion of the vaporization chamber, and configured to supply a mixed fluid in which a first carrier gas and a liquid precursor are mixed, toward the second portion. A second fluid supply part is configured to supply a second carrier gas toward the mixed fluid at the second portion.

A CVD reactor for deposition of silicon carbide material on silicon carbide substrates, may comprise: an upper gas manifold and a lower gas manifold; and a substrate carrier comprising a gas tight rectangular box open on upper and lower surfaces, a multiplicity of planar walls across the width of the box, the walls being equally spaced in a row facing each other and defining a row of channels within the box, the walls comprising mounting fixtures for a plurality of substrates and at least one electrically resistive heater element; wherein the upper gas manifold and the lower gas manifold are configured to attach to the upper and lower surfaces of the substrate carrier, respectively, connect with upper and lower ends of the channels, and isolate gas flows in odd numbered channels from gas flows in even numbered channels, wherein the channels are numbered in order along the row; and wherein said electrically resistive heater elements and said mounting fixtures are coated with a material able to withstand exposure to (i) chemicals for removal of silicon carbide, such as ClF.sub.3, and (ii) process temperatures up to 1700° C., examples of the material including tantalum carbide, diamond and boron nitride.

An apparatus for the vacuum treatment of substrates in a vacuum chamber includes a substrate support device with a pylon which can be rotated about a longitudinal axis and has holding means for substrates and a plasma discharge device assigned to the pylon. The plasma discharge device includes more than two plate-shaped electrodes having excitation areas, the excitation areas of which are all oriented in the direction of the pylon and a power supply device for the excitation of a plasma discharge, by at least one electrical voltage applied to at least two of the electrodes, is provided, the excited plasma acting at least on parts of the pylon and on substrates that can be arranged on them. A process performs the vacuum coating by the apparatus.

A substrate guide of the present invention is provided on a carrier frame of a carrier which holds a substrate substantially vertically so that a surface of the substrate is in a substantially vertical direction and supports the substrate by being in contact with at least a peripheral edge end surface portion of the substrate. The substrate guide includes a base attached to the carrier frame, a substrate support which comes into contact with the peripheral edge end surface portion of the substrate held by the carrier and is attached to the base to be movable in a normal direction of the peripheral edge end surface portion in a direction parallel to the surface of the substrate, and a force-applying member which applies a force to the substrate support toward the substrate with respect to the base.

A plasma treatment apparatus includes a plurality of plasma treatment chambers S2 to S6 in which a plasma treatment is performed on a base material X, a tray Y configured to hold the base material X in a standing posture, and a lift mechanism 10 configured to continuously convey the tray Y to the plurality of plasma treatment chambers S2 to S6 in order to continuously perform a plasma treatment even when the base material is difficult to wind on a roll.

A method for forming a film is provided. The method includes sequentially placing a first wafer, a second wafer, and a third wafer in a chamber. The first wafer is separated from the second wafer by a first distance, the second wafer is separated from the third wafer by a second distance, and the first distance is smaller than the second distance. At least one process gas is introduced sequentially passing through the first wafer, the second wafer and the third wafer in the chamber.

Apparatus and methods for providing backside pressure control and edge purge gas to a substrate in a processing chamber. A support region of a substrate support is defined by an outer band. The support region comprises one or more openings in the top surface of the substrate support. The outer band comprises a plurality of spaced apart posts. Processing chambers, methods of processing a substrate and non-transitory computer-readable medium containing instructions to process a substrate are also disclosed.