A reflector includes a reflector body arranged to overlap a reaction chamber of a semiconductor processing system. The reflector body has a grooved surface and a reflective surface extending between a first longitudinal edge of the reflector body and a second longitudinal edge of the reflector body, the reflective surface spaced apart from the grooved surface by a thickness of the reflector body. The grooved surface and the reflective surface define a pyrometer port, two or more elongated slots, and two or more shortened extending through the thickness of the reflector body. The shortened slots outnumber the elongated slots to bias issue of a coolant against the reaction chamber toward the second longitudinal edge of the reflector body. Cooling kits, semiconductor processing systems, and methods of cooling a reaction chamber during deposition of a film onto a substrate supported within the reaction chamber are also described.

Disclosed are a method for preheating a substrate treating apparatus capable of shortening a preheating time and simultaneously performing a maintenance operation, and a computer program for the same. The method includes setting a parameter related to preheating of a preheating target component among components constituting the substrate treating apparatus; and preheating the preheating target component based on the set parameter, wherein a movement range of the preheating target component is limited to a value within a movable range.

Disclosed are a method for preheating a substrate treating apparatus capable of shortening a preheating time and simultaneously performing a maintenance operation, and a computer program for the same. The method includes setting a parameter related to preheating of a preheating target component among components constituting the substrate treating apparatus; and preheating the preheating target component based on the set parameter, wherein a movement range of the preheating target component is limited to a value within a movable range.

Implementations of the present disclosure generally relate to one or more flow ratio controllers and one or more gas injection inserts in the semiconductor processing chamber. In one implementation, an apparatus includes a first flow ratio controller including a first plurality of flow controllers, a second flow ratio controller including a second plurality of flow controllers, and a gas injection insert including a first portion and a second portion. The first portion includes a first plurality of channels and the second portion includes a second plurality of channels. The apparatus further includes a plurality of gas lines connecting the first and second pluralities of flow controllers to the first and second pluralities of channels. One or more gas lines of the plurality of gas lines are each connected to a channel of the first plurality of channels and a channel of the second plurality of channels.

Implementations of the present disclosure generally relate to one or more flow ratio controllers and one or more gas injection inserts in the semiconductor processing chamber. In one implementation, an apparatus includes a first flow ratio controller including a first plurality of flow controllers, a second flow ratio controller including a second plurality of flow controllers, and a gas injection insert including a first portion and a second portion. The first portion includes a first plurality of channels and the second portion includes a second plurality of channels. The apparatus further includes a plurality of gas lines connecting the first and second pluralities of flow controllers to the first and second pluralities of channels. One or more gas lines of the plurality of gas lines are each connected to a channel of the first plurality of channels and a channel of the second plurality of channels.

There is provided a method of manufacturing a semiconductor device, including forming a metal nitride film substantially not containing a silicon atom on a substrate by sequentially repeating: (a) supplying a metal-containing gas and a reducing gas, which contains silicon and hydrogen and does not contain a halogen, to the substrate in a process chamber by setting an internal pressure of the process chamber to a value which falls within a range of 130 Pa to less than 3,990 Pa during at least the supply of the reducing gas, wherein (a) includes a timing of simultaneously supplying the metal-containing gas and the reducing gas; (b) removing the metal-containing gas and the reducing gas that remain in the process chamber; (c) supplying a nitrogen-containing gas to the substrate; and (d) removing the nitrogen-containing gas remaining in the process chamber.

There is provided a method of manufacturing a semiconductor device, including forming a metal nitride film substantially not containing a silicon atom on a substrate by sequentially repeating: (a) supplying a metal-containing gas and a reducing gas, which contains silicon and hydrogen and does not contain a halogen, to the substrate in a process chamber by setting an internal pressure of the process chamber to a value which falls within a range of 130 Pa to less than 3,990 Pa during at least the supply of the reducing gas, wherein (a) includes a timing of simultaneously supplying the metal-containing gas and the reducing gas; (b) removing the metal-containing gas and the reducing gas that remain in the process chamber; (c) supplying a nitrogen-containing gas to the substrate; and (d) removing the nitrogen-containing gas remaining in the process chamber.

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.

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.