There is provided technique that includes (a) adsorbing a first adsorption inhibitor to a first portion of a substrate by supplying the first adsorption inhibitor to the substrate at a first temperature; (b) after (a), forming a film on a second portion of the substrate by supplying a processing gas to the substrate at a second temperature; (c) after (b), removing at least a part of the first adsorption inhibitor, which is adsorbed to the substrate, at a third temperature higher than the second temperature; (d) after (c), supplying a second adsorption inhibitor to the substrate at a fourth temperature; (e) after (d), supplying the processing gas to the substrate at the second temperature higher than the fourth temperature; and (f) after (e), removing at least a part of the second adsorption inhibitor, which is adsorbed to the substrate, at the third temperature higher than the second temperature.

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.

A wafer cleaning apparatus is provided. The wafer cleaning apparatus includes comprising a chamber configured to be loaded with a wafer, a nozzle on the wafer and configured to provide liquid chemicals on an upper surface of the wafer, a housing under the wafer, a laser module configured to irradiate laser on the wafer, a transparent window disposed between the wafer and the laser module, and a controller configured to control on/off of the laser module, wherein the controller is configured to control repetition of turning the laser module on and off, and retain temperature of the wafer within a temperature range, and a ratio of time when the laser module is on in one cycle including on/off of the laser module is 30% to 50%.

The invention provides a ceramic device enabling more complex, elaborate patterns for resistance heating elements or electrodes. A ceramic device includes a ceramic substrate consisting of a ceramic sintered body and including at least a base layer, an intermediate layer laminated over the base layer, and an overlayer laminated over the intermediate layer; and an electrifiable resistance heating element or electrode having a predetermined pattern extending in a planar shape and being embedded in the ceramic substrate. A horizontal surface is defined in the upper surface of the intermediate layer, along which the resistance heating element or electrode is arranged, and the overlayer is laminated onto the upper surface of the intermediate layer to cover the resistance heating element or electrode.

An apparatus for controlling the temperature of a substrate is equipped with a plate-type main body having a substrate placement area, a first temperature-control device for controlling the temperature of the main body using a first temperature-control fluid, having a first plurality of separate annular channels inside the main body, a second temperature-control device for controlling the temperature of the main body using a second temperature-control fluid, having a second plurality of separate annular channels inside the main body, wherein the first temperature-control fluid is supplied to the first plurality of annular channels through a first tube and removed therefrom through a second tube, wherein the second temperature-control fluid is supplied to the second plurality of annular channels through a third tube and removed therefrom through a fourth tube, wherein the main body has a first to fourth hole that communicate with the first plurality of separate annular channels and the second plurality of separate annular channels, wherein the first to fourth tubes are placed in the first to fourth holes of the main body.

Provided is a high pressure heat treatment apparatus including: an internal chamber accommodating an object to be heat-treated; an external chamber including a housing and a partition plate partitioning the housing into a high-temperature zone accommodating the internal chamber and a low-temperature zone having a lower temperature than the high-temperature zone, the partition plate including a discharge hole for allowing the high-temperature zone and the low-temperature zone to communicate with each other; a gas supply module configured to supply a process gas for the heat treatment to the internal chamber at a first pressure higher than that of the atmosphere, and supply a protective gas to the high-temperature zone and the low-temperature zone at a second pressure set in relation to the first pressure; and a discharge module configured to open the discharge hole to discharge the protective gas in the high-temperature zone to the low-temperature zone.

The present invention relates to a bonding apparatus for a power terminal of a heating plate, for bonding the power terminal supplying power to a heating wire of a substrate. The bonding apparatus for a power terminal of a heating plate comprises: a chamber; a stage which is disposed in an inner space of the chamber and on which the substrate is placed; an upper press portion disposed in the inner space of the chamber to face the stage, provided to be vertically movable, and having a terminal fixing portion configured to fix the power terminal; and an elevating driver configured to move the upper press portion up and down, wherein the terminal fixing portion further includes a magnetic holder configured to hold the power terminal by a magnetic force.

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.

There is provided a method of forming a carbon film on a workpiece, which includes: loading the workpiece into a process chamber; supplying a gas containing a boron-containing gas into the process chamber to form a seed layer composed of a boron-based thin film on a surface of the workpiece; and subsequently, supplying a hydrocarbon-based carbon source gas and a pyrolysis temperature lowering gas containing a halogen element and which lowers a pyrolysis temperature of the hydrocarbon-based carbon source gas into the process chamber, heating the hydrocarbon-based carbon source gas to a temperature lower than the pyrolysis temperature to pyrolyze the hydrocarbon-based carbon source gas, and forming the carbon film on the workpiece by a thermal CVD.

In substrate processing, by supplying a first processing liquid onto an upper surface 91 of a substrate 9 held in a horizontal state, a liquid film 81 of the first processing liquid which entirely covers the upper surface 91 is formed. Further, by heating the substrate 9, a vapor layer 82 of the first processing liquid is formed between the upper surface 91 and the liquid film 81 of the first processing liquid on the upper surface 91. Then, by supplying a second processing liquid onto the upper surface 91 of the substrate 9, the liquid film 81 of the first processing liquid is removed from the upper surface 91. It is thereby possible to appropriately remove extraneous matters 89 from the upper surface 91 of the substrate 9, which are taken in the liquid film 81 of the first processing liquid as the vapor layer 82 is formed.