An apparatus for processing a wafer comprises: a rotatable chuck adapted to receive a wafer; a heating assembly comprising an array of heating elements arranged to heat a wafer received by the rotatable chuck; an image sensor arranged to detect electromagnetic radiation from a surface of the wafer; and a controller configured to control supply of power to the array of heating elements based on a measurement output of the image sensor.

There is provided a technique capable of capable of preventing a substrate from being metal-contaminated by a component constituting a furnace opening. According to one aspect thereof, there is provided a furnace opening structure including: an upper inlet structure connected to a first protrusion provided at a lower portion of a reaction tube via a first seal, and configured to support the reaction tube; a lower inlet structure connected to the upper inlet structure via a second seal; and a fixing structure connected to the upper inlet structure and configured to fix the first protrusion, wherein the upper inlet structure is provided below an exhaust pipe provided at the lower portion of the reaction tube, and wherein the first protrusion is configured to be capable of being cooled by circulating a cooling medium through flow paths provided inside the upper inlet structure and the fixing structure, respectively.

A semiconductor processing tool is disclosed, the tool having a frame forming at least one chamber with an opening and having a sealing surface around a periphery of the opening, a door configured to interact with the sealing surface for sealing the opening, the door having sides perpendicular to the door sealing surface and perpendicular to a transfer plane of a substrate, and at least one drive located on the frame to a side of at least one of the sides that are substantially perpendicular to the door sealing surface and substantially perpendicular to the transfer plane of the substrate, the drive having actuators located at least partially in front of the sealing surface and the actuators being coupled to one of the sides of the door for moving the door from a sealed position. The at least one drive is located outside of a substrate transfer zone.

A laser structure may include a substrate, an active region arranged on the substrate, and a waveguide arranged on the active region. The waveguide may include a first surface and a second surface that join to form a first angle relative to the active region. A material may be deposited on the first surface and the second surface of the waveguide.

An apparatus for depositing a thin layer and associated method, the apparatus including a process chamber; a support in the process chamber, substrates being supportable on the support at different heights; a gas injector configured to inject a gas into the process chamber; and a heater configured to heat the process chamber, wherein the gas injector includes a first injector configured to inject a first gas; and a second injector configured to inject a second gas, a flow rate of the first gas injected from the first injector ranges from 120 sccm to 240 sccm, and a flow rate of the second gas injected from the second injector ranges from 1,200 sccm to 2,400 sccm.

An apparatus for treating a substrate includes a plurality of heat treatment chambers and a plurality of sensors that determine whether the plurality of heat treatment chambers are mounted. The number of the plurality of sensors corresponds to the number of the plurality of heat treatment chambers. The plurality of sensors are B contact sensors.

Aspects of the present disclosure relate to methods, systems, and apparatus for conducting a radical treatment operation on a substrate prior to conducting an annealing operation on the substrate. In one implementation, a method of processing semiconductor substrates includes pre-heating a substrate, and exposing the substrate to species radicals. The exposing of the substrate to the species radicals includes a treatment temperature that is less than 300 degrees Celsius, a treatment pressure that is less than 1.0 Torr, and a treatment time that is within a range of 8.0 minutes to 12.0 minutes. The method includes annealing the substrate after the exposing of the substrate to the species radicals. The annealing includes exposing the substrate to molecules, an anneal temperature that is 300 degrees Celsius or greater, an anneal pressure that is within a range of 500 Torr to 550 Torr, and an anneal time that is less than 4.0 minutes.

Disclosed are a device and method for continuously performing grain boundary diffusion and heat treatment, characterized in that the alloy workpiece or the metal workpiece are arranged in a relatively independent processing box together with a diffusion source; the device comprises, in successive arrangement, a grain boundary diffusion chamber, a first cooling chamber, a heat treatment chamber, and a second cooling chamber, and a transfer system provided between various chambers for delivering the processing box; each of the first cooling chamber and the second cooling chamber uses an air cooling system, and the cooling air temperature of the first cooling chamber is above 25° C. and at least differs by 550° C. from the grain boundary diffusion temperature of the grain boundary diffusion chamber; the cooling air temperature of the second cooling chamber is above 25° C. and at least differs by 300° C. from the heat treatment temperature of the heat treatment chamber; and the cooling chamber has a pressure of 50 kPa to 100 kPa. The device provided by the present invention can increase the cooling rate and production efficiency, and improve product consistency.

Herein disclosed are systems and methods related to solid source chemical sublimator vessels and corresponding deposition modules. The solid source chemical sublimator can include a housing configured to hold solid chemical reactant therein. A lid may be disposed on a proximal portion of the housing. The lid can include a fluid inlet and a fluid outlet and define a serpentine flow path within a distal portion of the lid. The lid can be adapted to allow gas flow within the flow path. The solid source chemical sublimator can include a filter that is disposed between the serpentine flow path and the distal portion of the housing. The filter can have a porosity configured to restrict a passage of a solid chemical reactant therethrough.

A sealing structure of a gas supply line assembly connected to a processing chamber for processing a substrate in a vacuum atmosphere is provided. The sealing structure includes a first pipe member constituting the gas supply line assembly and having an end surface where an opening communicating with the processing chamber is formed, a second pipe member constituting the gas supply line assembly and having a facing surface facing the end surface of the first pipe member, and a sealing member made of an elastomer disposed between the end surface of the first pipe member and the facing surface of the second pipe member to surround the opening. The sealing structure further includes a sheet-shaped porous member disposed between the end surface of the first pipe member and the facing surface of the second pipe member to surround a vicinity of the sealing member.