According to one aspect of a technique the present disclosure, there is provided a substrate processing apparatus including: a reaction tube in which a substrate is accommodated; a nozzle accommodation structure provided at a side surface of the reaction tube and extending in a direction parallel to a surface of the substrate; a gas supply nozzle inserted in the nozzle accommodation structure and extending from an outside of the reaction tube to an inside of the reaction tube; and a first gas supply structure through which a first gas is supplied to the gas supply nozzle.

The present disclosure relates to an apparatus for trapping multiple reaction by-products for a semiconductor process, in which in order to separate, with the single trapping apparatus, reaction by-product mixtures contained in unreacted gases discharged after a process of depositing multiple different thin film layers is performed in a process chamber during a semiconductor manufacturing process, a trapping region division part is provided, which divides a heat distribution region into trapping regions for respective reaction by-products while controlling a flow in a movement direction of an introduced unreacted gas, thereby trapping a reaction by-product aggregated in the form of a thin film in a relatively high-temperature region by using a first internal trapping tower in a front region, and trapping a reaction by-product aggregated in the form of powder in a relatively low-temperature region by using a second internal trapping tower in a rear region.

A substrate processing apparatus includes: a process chamber configured to process a substrate; a precursor gas supply section for supplying a precursor gas; a reactant gas supply section for supplying a reactant gas; an exhauster for exhausting the process chamber; a plasma generator including first and second plasma generators for converting the reactant gas into plasma to activate the reactant gas, the first and second plasma generators being disposed so that a straight line passing through the center of the process chamber and the exhauster is interposed therebetween; and a gas rectifier including a first partition member disposed along an inner wall of the process chamber between the precursor gas supply section and the first plasma generator, and a second partition member disposed at an outer circumferential portion of the substrate along an inner wall of the process chamber between the precursor gas supply section and the second plasma generator.

Embodiments described herein provide a chamber having a gas flow inlet guide to uniformly deliver process gas. The gas flow inlet guide having a flow guide bottom plate having an opening. A top plate is disposed over the flow guide bottom plate and a plasma blocker is disposed over the opening. The plasma blocker includes one or more apertures sized based one or more of a plasma density, an electron temperature, an ion temperature, or a characteristic of a process gas.

The present disclosure provides a thin-film-deposition equipment for detecting shielding mechanism, which includes a reaction chamber, a carrier, a shielding mechanism and two distance sensors. The carrier and the shielding mechanism is partially disposed within the reaction chamber. The shielding mechanism includes two shield unit and a driver. The driver interconnects and drives the two shield units to sway in opposite directions and into an open state and a shielding state. Each of the two shield unit is disposed with a reflective surface for each of the two distance sensors to respectively project optical beams onto and detect a distances therebetween when the two shield units are operated in the shielding state, such that to confirm that the shielding mechanism is in the shielding state.

Aspects generally relate to systems, methods, and apparatus for applying a bias voltage to an ion blocker plate during substrate processing operations. In one aspect, the bias voltage is a negative direct current (DC) voltage. In one aspect, the bias voltage is a radio frequency (RF) voltage having a bias frequency of 2 MHz or less. In one implementation, a system for processing substrates includes a processing chamber. The processing chamber includes a processing volume, a pedestal positioned in the processing volume, and a lid assembly. The system includes a power line coupled to a faceplate of the lid assembly to supply a radio frequency (RF) power to the faceplate. The system includes a bias voltage line coupled to an ion blocker plate of the lid assembly to supply a bias voltage to the ion blocker plate.

Embodiments of heated lids for a process chamber are provided herein. In some embodiments, a heated lid includes: a body having a central region and a peripheral region, wherein the body includes a central opening in the central region, wherein the peripheral region includes a plurality of vertical slots that extend into an upper surface of the body and arranged along a circle to provide a thermal break, and wherein the body includes one or more annular plenums that extend into the upper surface of the body and a plurality of holes extending through a bottom surface of the one or more annular plenums to a lower surface of the body; a first heater ring having one or more heating elements disposed therein, wherein the first heater ring is coupled to the central region of the body; and a second heater ring having one or more heating elements disposed therein.

A film forming system includes: a film forming apparatus which includes a processing container, a stage provided in the processing container, a structure provided in the processing container and having recesses, and a window provided on a wall surface of the processing container; a measurement device which includes a light emitter, a light receiver, and a measurer configured to measure a light reflectance for each wavelength in the structure based on an intensity of light emitted to the structure and an intensity of light reflected from the structure; and a control device which includes an estimator configured to estimate a thickness of a film formed on a substrate based on the light reflectance for each wavelength in the structure, and a controller configured to stop film formation on the substrate when the estimated thickness of the film reaches a predetermined thickness.

Described herein is a technique capable of properly attaching a nozzle to a reaction tube. According to one aspect thereof, there is provided a nozzle installation jig including: a lower plate configured to make contact with a process vessel in a vicinity of a lower end opening of the process vessel in which a nozzle is provided; a frame fixed to the lower plate and extending upward with respect to the lower plate; an upper plate fixed to the frame and provided with a sensor configured to detect a position of the nozzle in the process vessel; and a notification device configured to transmit a notification to an operator according to a detection result of the sensor.

A film forming apparatus configured to form a metal oxide film or a metal nitride film through atomic layer deposition by alternately introducing metal compound gas and an OH radical or an NH radical in a reaction container. The film forming apparatus including: the reaction container; and at least one plasma generator provided outside the reaction container and configured to generate a first plasma including an oxygen radical or a nitrogen radical when oxygen or nitrogen is supplied and generate a second plasma including a hydrogen radical when hydrogen is supplied. The OH radical is generated by collision between the oxygen radical and the hydrogen radical or the NH radical is generated by collision between the nitrogen radical and the hydrogen radical in a downstream region from an outlet of the at least one plasma generator to an inner space of the reaction container.