A CVD apparatus for manufacturing a III-nitride-based layer having a rotating wafer carrier positioned inside a reaction chamber that receives a mixture of a nitrogen gas source and a group III element gas source. Recesses are formed within the wafer carrier, each including a satellite disc of thickness x for accepting a wafer of thickness t. The satellite disc includes a peripheral notch of height a, and a notch thickness of x−a=b. A peripheral retaining ring includes a vertical rise portion extending a distance of e+f and a laterally-extending portion, the laterally-extending portion engaging the satellite disc notch. A gap c is formed between the substrate and a surface of the satellite disc. The relationship of a+b+c+t=b+e+f is satisfied such that laminar flow occurs in the region of the retaining ring.

Embodiments of mechanisms for processing a semiconductor wafer are provided. A method for processing a wafer includes providing a wafer process apparatus. The wafer process apparatus includes a chamber and a stage positioned in the chamber for supporting the semiconductor wafer. The method also includes supplying a process gas to the semiconductor wafer via a discharging assembly that is adjacent to the stage. The discharging assembly includes a discharging passage configured without a vertical flow path section.

Aspects of the present disclosure provide systems and apparatuses for a substrate processing assembly with a laminar flow cavity gas injection for high and low pressure. A dual gas reservoir assembly is provided in a substrate processing chamber, positioned within a lower shield assembly. A first gas reservoir is in fluid communication with a processing volume of the substrate processing assembly via a plurality of gas inlet, positioned circumferentially about the processing volume. A second gas reservoir is positioned circumferentially about the first gas reservoir, coupled therewith via one or more reservoir ports. The second gas reservoir is in fluid communication with a first gas source. A recursive path gas assembly is positioned in an upper shield body adjacent to an electrode to provide one or more gases to a dark space gap.

A processing apparatus includes: a processing container having a substantially cylindrical shape; a gas supply pipe configured to supply a gas into the processing container; and an exhaust duct extending in a longitudinal direction of the processing container to form an exhaust window configured to exhaust the gas from an interior of the processing container, a first exhaust flow path configured to exhaust, from a first side in a longitudinal direction of the exhaust window, the gas exhausted through the exhaust window, and a second exhaust flow path configured to exhaust, from a second side in the longitudinal direction of the exhaust window, the gas exhausted through the exhaust window, wherein the exhaust duct includes: a first gas introduction part configured to introduce a ballast gas into the first exhaust flow path, and a second gas introduction part configured to introduce the ballast gas into the second exhaust flow path.

Embodiments disclosed herein include a plasma treatment chamber, comprising one or more sidewalls. A support surface within the one or more sidewalls holds a workpiece. A first gas injector along the one or more sidewalls injects a first gas flow in a first direction generally parallel to and across a surface of the workpiece. A first pump port along the one or more sidewalls generally opposite of the first gas injector pumps out the first gas flow. A second gas injector along the one or more sidewalls injects a second gas flow in a second direction generally parallel to and across the surface of the workpiece. A second pump port along the one or more sidewalls generally opposite of the second gas injector pumps out the second gas flow.

Embodiments disclosed herein include a plasma treatment chamber, comprising one or more sidewalls. A support surface within the one or more sidewalls holds a workpiece. A first gas injector along the one or more sidewalls injects a first gas flow in a first direction generally parallel to and across a surface of the workpiece. A first pump port along the one or more sidewalls generally opposite of the first gas injector pumps out the first gas flow. A second gas injector along the one or more sidewalls injects a second gas flow in a second direction generally parallel to and across the surface of the workpiece. A second pump port along the one or more sidewalls generally opposite of the second gas injector pumps out the second gas flow. The first and second gas flows comprise a process gas mixture and/or an independent gas injection (IGI) mixture.

The present disclosure relates to an apparatus for processing a substrate, and more particularly, to an apparatus for processing a substrate, which is capable of allowing a substrate processing gas to smoothly flow on the substrate. The apparatus for processing the substrate in accordance an exemplary embodiment may form a laminar flow through a gas supply unit disposed on one side of an inner reaction tube and an exhaust duct disposed on the other side of the inner reaction tube, which faces the gas supply unit, to extend up to the outside of an accommodation region of a pedestal in an accommodation space of the inner reaction tube and control a flow of a substrate processing gas supplied onto the substrate.

Described herein is a technique capable of suppressing a deviation in a thickness of a film formed on a substrate. According to one aspect of the technique of the present disclosure, a substrate processing apparatus includes a substrate retainer capable of supporting substrates; a cylindrical process chamber including a discharge part and supply holes; partition parts arranged in the circumferential direction to partition supply chambers communicating with the process chamber through the supply holes; nozzles provided with an ejection hole; and gas supply pipes. The supply chambers includes a first nozzle chamber and a second nozzle chamber, the process gas includes a source gas and an assist gas, the nozzles includes a first nozzle for the assist gas flows and a second nozzle disposed in the second nozzle chamber and through which the source gas flows, and the first nozzle is disposed adjacent to the second nozzle.

A substrate processing apparatus includes a reaction chamber including an inlet through which a reaction gas is supplied and an outlet through which residue gas is exhausted; a plurality of ionizers located at a front end of the inlet and configured to ionize the reaction gas supplied through the inlet; and a heater configured to heat the reaction chamber. The plurality of ionizers include a first ionizer configured to ionize the reaction gas positively; and a second ionizer configured to ionize the reaction gas negatively.

Described herein is a technique capable of suppressing an undesired gas and a foreign substance from entering a supply buffer. According to one aspect thereof, there is provided a substrate processing apparatus including: a process vessel accommodating substrates and vertically arranged along an arrangement direction wherein the substrates are processed in the process vessel; a nozzle provided in the process vessel, provided with first openings arranged along the arrangement direction and configured to distribute and supply a gas to the substrates; and a supply buffer provided in the process vessel, accommodating the nozzle, and provided with second openings arranged along the arrangement direction and open toward a substrate arrangement region in the process vessel where the substrates are arranged, wherein at least one among the first openings is arranged to be prevented from directly facing the second openings.