There is provided a technique that includes executing a process recipe for processing a substrate; and executing a correction recipe for checking a characteristic value of a supply valve installed at a process gas supply line, wherein the act of executing the correction recipe comprises: supplying an inert gas into the process gas supply line for a certain period of time in a state where an adjusting valve that is installed at an exhaust portion of a process furnace and adjusts an internal pressure of the process furnace is fully opened; detecting a pressure value in a supply pipe provided with the supply valve while supplying the inert gas into the process gas supply line in the state where the adjusting valve is fully opened; and calculating the characteristic value of the supply valve based on the detected pressure value.

A film forming method includes forming a film by sequentially performing operations for each of a plurality of kinds of reaction gases, the operations being of storing the reaction gas in a storage part to raise a pressure in the storage part to a first pressure and then discharging the reaction gas into the process vessel, while continuously supplying the counter gas, and purging by repeating multiple times operations of storing a purge gas in the storage part provided in the reaction gas supply passage to raise the pressure in the storage part to a second pressure higher than the first pressure, and discharging the purge gas into the process vessel. A flow rate of the counter gas supplied into the process vessel in the purging is smaller than a flow rate of the counter gas supplied into the process vessel in the forming the film.

According to one embodiment of the present invention, a method for forming a thin film using a surface protection material comprises: a surface protection layer forming step of forming a surface protection layer on the surface of a substrate by supplying a surface protection material to the inside of a chamber in which the substrate is placed; a step of performing a primary purging of the inside of the chamber; a metal precursor supply step of supplying a metal precursor to the inside of the chamber; a step of performing a secondary purging of the inside of the chamber; and a thin film forming step of supplying a reactive material to the inside of the chamber so as to react with the metal precursor and form a thin film.

A substrate processing method includes forming an adsorption layer on a substrate by supplying a silicon-containing gas to the substrate; performing a modification by generating plasma containing He; and generating plasma of a reaction gas to cause the plasma to react with the adsorption layer, wherein the forming the adsorption layer, the performing the modification, and the generating the plasma are repeated to form a silicon-containing film.

A substrate processing apparatus, including a reaction chamber to process a substrate, a photon source to provide the reaction chamber with photons from the top side of the reaction chamber, a substrate support to support the substrate, a chemical inlet to provide the reaction chamber with a reactive chemical; and a chemical outlet to exhaust gases from the reaction chamber, the chemical outlet including a surface separating the reaction chamber from a surrounding space.

A chemical vapor deposition (CVD) apparatus is provided. The CVD apparatus includes a CVD chamber including multiple wall portions. A pedestal is disposed inside the CVD chamber, configured to support a substrate. A gas inlet port is disposed on one of the wall portions and below a substrate support portion of the pedestal. In addition, a gas flow guiding member is disposed inside the CVD chamber, coupled to the gas inlet port, and configured to dispense cleaning gases from the gas inlet port into the CVD chamber.

A film-forming method includes: forming a first film by performing an operation of forming a unit film a plurality of times, the operation including sub-step of supplying a first raw material gas containing a first element to a substrate and causing the first raw material gas to be adsorbed thereon, and sub-step of supplying a first reaction gas to the substrate; and forming a second film on the substrate by performing an operation of forming a unit film at least once, the operation including sub-step of supplying a second raw material gas containing a second element to the substrate and causing the second raw material gas to be adsorbed thereon, and sub-step of supplying a second reaction gas to the substrate, wherein a mixed film is formed by performing the forming the first film and the forming the second film, respectively once, or a plurality of times.

Methods of forming graphene hard mask films are disclosed. Some methods are advantageously performed at lower temperatures. The substrate is exposed to an aromatic precursor to form the graphene hard mask film. The substrate comprises one or more of titanium nitride (TiN), tantalum nitride (TaN), silicon (Si), cobalt (Co), titanium (Ti), silicon dioxide (SiO.sub.2), copper (Cu), and low-k dielectric materials.

The present inventive concept relates to a substrate processing apparatus and a spray module of the substrate processing apparatus, the substrate processing apparatus comprising: a chamber for providing a processing space; a lid for covering the upper portion of the chamber; a substrate support portion which supports at least one substrate and rotates about a rotary shaft; a gas spray portion which is above the substrate support portion in a diameter direction from the rotary shaft of the substrate support portion and which sprays a processing gas; and a measuring portion which is arranged to be in parallel with or to be inclined in a direction at a certain angle with respect to the diameter direction on a measurement position that is spaced apart from the diameter direction and which measures the temperature of the substrate supported by the substrate support portion or the temperature of the substrate support portion.

A substrate processing apparatus includes: a rotary table provided in a processing container; a rotation mechanism configured to rotate the rotary table; recesses provided on an upper surface of the rotary table along a rotation direction of the rotary table and configured to accommodate substrates, respectively; a processing gas supply provided above the rotary table and configured to supply a processing gas onto the rotary table to process each of the substrates; a heater configured to heat the rotary table; a support configured to support the substrates in upper regions above the recesses so that the heater heats the substrates before being accommodated in the recesses; and an elevating mechanism configured to raise and lower the support relative to the rotary table so that the substrates are collectively moved from the upper regions into the recesses.