There is provided a technique that includes: (a) heating a substrate to 445° C. or more and 505° C. or less; (b) supplying a molybdenum-containing gas to the substrate; and (c) supplying a reducing gas to the substrate, wherein a molybdenum-containing film is formed on the substrate by performing (b) and (c) one or more times after performing (a).

There is provided a technique that includes: (a) heating a substrate to 445° C. or more and 505° C. or less; (b) supplying a molybdenum-containing gas to the substrate; and (c) supplying a reducing gas to the substrate, wherein a molybdenum-containing film is formed on the substrate by performing (b) and (c) one or more times after performing (a).

A heat treatment apparatus includes a processing container that accommodates a processing target; a heater that heats the processing target accommodated in the processing container; and a controller that controls an overall operation of the heat treatment apparatus. The controller controls heating by the heater according to a set temperature of the heater; monitors the processing container in which the processing target is accommodated based on a monitoring condition of a protection function for the processing target; and when an upper limit time of monitoring elapses while the monitoring condition is being satisfied, changes the set temperature of the heater to a set temperature of the protection function.

A heat treatment apparatus includes a processing container that accommodates a processing target; a heater that heats the processing target accommodated in the processing container; and a controller that controls an overall operation of the heat treatment apparatus. The controller controls heating by the heater according to a set temperature of the heater; monitors the processing container in which the processing target is accommodated based on a monitoring condition of a protection function for the processing target; and when an upper limit time of monitoring elapses while the monitoring condition is being satisfied, changes the set temperature of the heater to a set temperature of the protection function.

In one aspect, a highly scalable diffusion-couple apparatus includes a transfer chamber configured to load a wafer into a process chamber. The process chamber is configured to receive the wafer substrate from the transfer chamber. The process chamber comprises a chamber for growth of a diffusion material on the wafer. A heatable bottom substrate disk includes a first heating mechanism. The heatable bottom substrate disk is fixed and heatable to a specified temperature. The wafer is placed on the heatable bottom substrate disk. A heatable top substrate disk comprising a second heating mechanism. The heatable top substrate disk is configured to move up and down along an x axis and an x prime axis to apply a mechanical pressure to the wafer on the heatable bottom substrate disk. While the heatable top substrate disk applies the mechanical pressure a chamber pressure is maintained at a specified low value. The first heating mechanism and the second heating mechanism can be independently tuned to any value in the working range.

In one aspect, a highly scalable diffusion-couple apparatus includes a transfer chamber configured to load a wafer into a process chamber. The process chamber is configured to receive the wafer substrate from the transfer chamber. The process chamber comprises a chamber for growth of a diffusion material on the wafer. A heatable bottom substrate disk includes a first heating mechanism. The heatable bottom substrate disk is fixed and heatable to a specified temperature. The wafer is placed on the heatable bottom substrate disk. A heatable top substrate disk comprising a second heating mechanism. The heatable top substrate disk is configured to move up and down along an x axis and an x prime axis to apply a mechanical pressure to the wafer on the heatable bottom substrate disk. While the heatable top substrate disk applies the mechanical pressure a chamber pressure is maintained at a specified low value. The first heating mechanism and the second heating mechanism can be independently tuned to any value in the working range.

A system. The system may include a first zone into which a first precursor is introduced; a second zone into which a second precursor is introduced; a third zone between the first zone and the second zone and in which a reactive species is generated; a fourth zone between the first zone and the third zone; a fifth zone between the second zone and the third zone; wherein a process gas is introduced into the fourth zone and the fifth zone; wherein the reactive species and the first precursor is mixed in the fourth zone and the reactive species and the second precursor is mixed in the fifth zone; and a substrate transport mechanism.

A process for densifying annular porous substrates by chemical vapour infiltration, includes providing a plurality of unit modules including a support plate on which is formed a stack of substrates, the support plate including a central gas inlet opening communicating with an internal volume formed by the central passages of the stacked substrates and gas outlet openings distributed angularly around the central opening, and a thermal mass cylinder disposed around the stack of substrates having a first end integral with the support plate and a second free end, forming stacks of unit modules in the chamber of a densification furnace, and injecting into the stacks of unit modules a gas phase including a gas precursor of a matrix material to be deposited within the porosity of the substrates.

A process for densifying annular porous substrates by chemical vapour infiltration, includes providing a plurality of unit modules including a support plate on which is formed a stack of substrates, the support plate including a central gas inlet opening communicating with an internal volume formed by the central passages of the stacked substrates and gas outlet openings distributed angularly around the central opening, and a thermal mass cylinder disposed around the stack of substrates having a first end integral with the support plate and a second free end, forming stacks of unit modules in the chamber of a densification furnace, and injecting into the stacks of unit modules a gas phase including a gas precursor of a matrix material to be deposited within the porosity of the substrates.

Provided are a bearing system and a power control method for a bearing device. The bearing system comprises a susceptor; a rotating shaft fixed under the susceptor, where the rotating shaft and the susceptor rotate synchronously; a heating wire located under the susceptor, where the heating wire comprises n heating wire units arranged in a circumferential direction of the susceptor, n≥2, and temperature of each of the heating wire units is independently controlled; and a power controller configured to: during rotation of the susceptor, control at least one of: a power of a heating wire unit directly under a down end of the susceptor to be less than a power of each of other heating wire units, or a power of a heating wire unit directly under an up end of the susceptor to be greater than a power of each of other heating wire units.