There is provided a technique that includes: loading an m-th substrate into a process chamber, wherein m is an integer less than n; forming a film on the m-th substrate by heating the m-th substrate in the process chamber; unloading the m-th substrate from the process chamber; waiting for a predetermined time in the process chamber, in a state where the substrates are not present in the process chamber, after the act of unloading; loading a next substrate, which is one of the n substrates to be processed next, into the process chamber, after the act of waiting; and forming a film on the next substrate by heating the next substrate in the process chamber.

A film forming method includes: preparing a substrate having a metal layer formed on a surface of a first region and an insulating layer formed on a surface of a second region, wherein the metal layer is formed of a first metal; forming a self-assembled film on a surface of the metal layer by supplying a source gas of the self-assembled film; after forming the self-assembled film, forming an oxide film of a second metal on the insulating layer through an atomic layer deposition method by repeating a supply of a precursor gas containing the second metal and a supply of an oxidizing gas; and reducing an oxide film of the first metal formed on a surface of the first metal by supplying a reducing gas after the supply of the oxidizing gas and before the supply of the precursor gas.

An apparatus for performing a deposition process on a semiconductor wafer includes a chamber, a wafer holder, and a shielding structure. The chamber contains a reaction area, the wafer holder is disposed in the chamber to hold the semiconductor wafer, and the reaction area is above the semiconductor wafer. The shielding structure is disposed in the chamber and isolates an inner sidewall of the chamber from the reaction area. The shielding structure includes a base member, a first member, and a second member. The base member is disposed between the inner sidewall of the chamber and the wafer holder. The first member is disposed on the base member and is windowless. The second member is disposed on the base member and within the first member, and the second member includes a sidewall provided with a first window to transfer the semiconductor wafer.

The disclosure relates to a substrate processing apparatus, comprising: a first reactor constructed and arranged to process a rack with a plurality of substrates therein; a second reactor constructed and arranged to process a substrate; and, a substrate transfer device constructed and arranged to transfer substrates to and from the first and second reactor. The second reactor may be provided with an illumination system constructed and arranged to irradiate ultraviolet radiation within a range from 100 to 500 nanometers onto a top surface of at least a substrate in the second reactor.

Methods and apparatus for a substrate processing chamber are provided herein. In some embodiments, a substrate processing chamber includes a chamber body having sidewalls defining an interior volume having a polygon shape; a selectively sealable elongated opening disposed in an upper portion of the chamber body for transferring one or more substrates into or out of the chamber body; a funnel disposed at a first end of the chamber body, wherein the funnel increases in size along a direction from an outer surface of the chamber body to the interior volume; and a pump port disposed at a second end of the chamber body opposite the funnel.

A method of making an atomic layer nanoribbon that includes forming a double atomic layer ribbon having a first monolayer and a second monolayer on a surface of the first monolayer, wherein the first monolayer and the second monolayer each contains a transition metal dichalcogenide material, oxidizing at least a portion of the first monolayer to provide an oxidized portion, and removing the oxidized portion to provide an atomic layer nanoribbon of the transition metal dichalcogenide material. Also provided are double atomic layer ribbons, double atomic layer nanoribbons, and single atomic layer nanoribbons prepared according to the method.

The invention relates to a method and an apparatus for the plasma treatment of containers. The essential aspect according to the method according to the invention is that, after the plasma treatment at the plasma station and before the container is filled, at least the container interior of the container is at least partially ventilated with a sterilization medium, i.e. is loaded with a sterilization medium.

The invention relates to a method and an apparatus for the plasma treatment of containers. The essential aspect according to the method according to the invention is that, after the plasma treatment at the plasma station and before the container is filled, at least the container interior of the container is at least partially ventilated with a sterilization medium, i.e. is loaded with a sterilization medium.

According to an embodiment of the present disclosure, a thin film forming apparatus includes a chamber, a plurality of gas inlets that are formed at an upper portion of the chamber and receive at least two reaction gas and precursors for radical reaction, and a radical unit configured to generate radicals by reacting the reaction gas provided through the gas inlet and deposit a thin film on a substrate by spraying the radicals and the precursors downward. The radical unit is configured with a plurality of plates, a precursor spray path is configured to be sprayed from the radical unit after the precursors are sprayed to a plurality of paths greater than precursor spray paths of the gas inlet in an uppermost plate among the plurality of plates, and a reaction gas spray path is configured not to overlap with the precursor spray path.

According to an embodiment of the present disclosure, a thin film forming apparatus includes a chamber, a plurality of gas inlets that are formed at an upper portion of the chamber and receive at least two reaction gas and precursors for radical reaction, and a radical unit configured to generate radicals by reacting the reaction gas provided through the gas inlet and deposit a thin film on a substrate by spraying the radicals and the precursors downward. The radical unit is configured with a plurality of plates, a precursor spray path is configured to be sprayed from the radical unit after the precursors are sprayed to a plurality of paths greater than precursor spray paths of the gas inlet in an uppermost plate among the plurality of plates, and a reaction gas spray path is configured not to overlap with the precursor spray path.