Provided is a system for stabilizing a flow of gas introduced into a sensor, wherein, in connection with manufacturing equipment comprising a process chamber, a process chamber vacuum pump installed to remove internal gas of the process chamber, and a sensor device configured to be able to receive the internal gas of the process chamber through a sensor connecting pipe and to detect components thereof, the system comprises a sensor connecting pipe and a bypass pipe branching off from the sensor connecting pipe such that a part of the gas can be directly discharged to the outside without being introduced into the sensor, and the system is accordingly configured to stably provide the sensor device with a part of the internal gas within a predetermined range per time, regardless of a change in the pressure state of the process chamber.

There is provided a shower head disposed in a processing container where a substrate is accommodated and configured to discharge a gas to the substrate in a shower pattern, comprising: a main body portion having a facing surface facing a stage disposed in the processing container to place the substrate thereon; a covering section that covers a surface formed on an opposite side of the facing surface of the main body portion, and forms, between the surface and the covering section, an exhaust space that is exhausted by an exhaust mechanism; a plurality of exhaust hole forming regions disposed on the facing surface apart from each other and each having a plurality of exhaust holes; a plurality of discharge holes disposed for each of the exhaust hole forming regions on the facing surface to surround each of the plurality of exhaust hole forming regions and configured to discharge the gas; a diffusion space disposed to be shared by the plurality of discharge holes, where the gas supplied to the main body portion is diffused to be supplied to each of the plurality of discharge holes; and an exhaust path disposed in the main body portion to be connected to the exhaust holes and opened to the exhaust space in order to exhaust the gas discharged from the discharge holes into the exhaust space.

The disclosure relates to a sequential infiltration synthesis apparatus comprising: a reaction chamber constructed and arranged to accommodate at least one substrate; a first precursor flow path to provide the first precursor to the reaction chamber when a first flow controller is activated; a second precursor flow path to provide a second precursor to the reaction chamber when a second flow controller is activated; a removal flow path to allow removal of gas from the reaction chamber; a removal flow controller to create a gas flow in the reaction chamber to the removal flow path when the removal flow controller is activated; and, a sequence controller operably connected to the first, second and removal flow controllers and the sequence controller being programmed to enable infiltration of an infiltrateable material provided on the substrate in the reaction chamber. The apparatus may be provided with a heating system.

A gas processing apparatus includes: a mounting part; a gas supply part located above the mounting part and having a plurality of first gas supply holes; a gas supply path forming part configured to form a supply path of a processing gas, the gas supply path forming part including a flat opposing surface which faces the gas supply part from above and defines a first diffusion space for diffusing the processing gas in a lateral direction; a recess surrounding a central portion of the opposing surface; and a plurality of gas dispersion portions located in the recess surrounding the central portion of the opposing surface without protruding from the opposing surface, each of the plurality of gas dispersion portions having a plurality of gas discharge holes extending along a circumferential direction so as to laterally disperse the processing gas supplied from the supply path in the first diffusion space.

A heat treatment apparatus includes: a processing container configured to accommodate and process a plurality of substrates in multiple tiers under a reduced-pressure environment; a first heater configured to heat the plurality of substrates accommodated in the processing container; a plurality of gas supply pipes configured to supply a gas to positions having different heights in the processing container; and a second heater provided on a gas supply pipe that supplies a gas to a lowermost position among the plurality of gas supply pipes, and configured to heat the gas in the gas supply pipe.

An exclusion ring for semiconductor wafer processing includes an outer circumferential segment having a first thickness and an inner circumferential segment having a second thickness, with the first thickness being greater than the second thickness. The top surface of an inner circumferential segment and the top surface of the outer circumferential segment define a common top surface for the exclusion ring. A plurality of flow paths is formed within the outer circumferential segment, with each of the flow paths extending radially through the plurality of flow paths provides for exhaust of a wafer edge gas from the pocket where a wafer has an edge thereof disposed below part of the inner circumferential portion. The exhausting of the wafer edge gas from the pocket prevents up-and-down movement of the exclusion ring when bowed wafers are processed.

The present disclosure concerns an atomic layer deposition device for area-selective deposition of a target material layer onto a deposition area of a substrate surface further comprising a non-deposition area. In use the substrate is conveyed along a plurality of deposition and separator spaces including at least two gas separator spaces provided with at least a separator gas inlet and a separator drain for, in use exposing the substrate to a separator gas flow. Wherein at least one of the gas separator spaces forms a combined separator-inhibitor gas flow comprising a separator gas and inhibitor moieties. The inhibitor moieties selectively adhering to the non-deposition area to form an inhibition layer reducing adsorption of precursor moieties. In a preferred embodiment the device includes a back-etching space to increase selectivity of the deposition process.

Provided are apparatuses and methods for performing deposition and etch processes in an integrated tool. An apparatus may include a plasma processing chamber that is a capacitively-coupled plasma reactor, and the plasma processing chamber can include a showerhead that includes a top electrode and a pedestal that includes a bottom electrode. The apparatus may be configured with an RF hardware configuration so that an RF generator may power the top electrode in a deposition mode and power the bottom electrode in an etch mode. In some implementations, the apparatus can include one or more switches so that at least an HFRF generator is electrically connected to the showerhead in a deposition mode, and the HFRF generator and an LFRF generator is electrically connected to the pedestal and the showerhead is grounded in the etch mode.

A method of depositing a silicon film on a recess formed in a surface of a substrate is provided. The substrate is placed on a rotary table in a vacuum vessel, so as to pass through first, second, and third processing regions in the vacuum vessel. An interior of the vacuum vessel is set to a first temperature capable of breaking an Si—H bond. In the first processing region, Si.sub.2H.sub.6 gas having a temperature less than the first temperature is supplied to form an SiH.sub.3 molecular layer on its surface. In the second processing region, a silicon atomic layer is exposed on the surface of the substrate, by breaking the Si—H bond in the SiH.sub.3 molecular layer. In the third processing region, by anisotropic etching, the silicon atomic layer on an upper portion of an inner wall of the recess is selectively removed.

A processing chamber such as a plasma etch chamber can perform deposition and etch operations, where byproducts of the deposition and etch operations can build up in a vacuum pump system fluidly coupled to the processing chamber. A vacuum pump system may have multiple roughing pumps so that etch gases can be diverted a roughing pump and deposition precursors can be diverted to another roughing pump. A divert line may route unused deposition precursors through a separate roughing pump. Deposition byproducts can be prevented from forming by incorporating one or more gas ejectors or venturi pumps at an outlet of a primary pump in a vacuum pump system. Cleaning operations, such as waferless automated cleaning operations, using certain clean chemistries may remove deposition byproducts before or after etch operations.