Apparatus and methods for processing a substrate including an injector unit, comprising a leading reactive gas port extending along a length of the injector unit, a trailing reactive gas port extending along the length of the injector unit, and a merge vacuum port forming a boundary around and enclosing the leading reactive gas port and the trailing reactive gas port.

A substrate processing apparatus includes a process chamber in which one or more substrates are processed; and a substrate support configured to support the one or more substrates in the process chamber. The substrate support includes one or more plate-shaped structures arranged in the substrate support in a manner corresponding to the one or more substrates, and a thickness of a central portion of a plate-shaped structure among the one or more plate-shaped structures is different from a thickness of an outer peripheral portion of the plate-shaped structure located outer of the central portion.

There is provided a technique which includes: forming a first film containing silicon, oxygen, carbon and nitrogen on a substrate by performing a first cycle a predetermined number of times, the first cycle including non-simultaneously performing: forming a first layer containing silicon, oxygen, carbon and nitrogen by simultaneously supplying first aminosilane and an oxidant to the substrate; and performing a first modifying process to the first layer under a first temperature; and performing a second modifying process to the first film under a second temperature that is higher than the first temperature.

Described herein is a technique capable of improving a film uniformity on a surface of a substrate and a film uniformity among a plurality of substrates including the substrate. According to one aspect thereof, there is provided a substrate processing apparatus including: a substrate retainer including: a product wafer support region, an upper dummy wafer support region and a lower dummy wafer support region; a process chamber in which the substrate retainer is accommodated; a first, a second and a third gas supplier; and an exhaust system. Each of the first gas and the third gas supplier includes a vertically extending nozzle with holes, wherein an upper of an uppermost hole and a lower end of a lowermost hole are arranged corresponding to an uppermost and a lowermost dummy wafer, respectively. The second gas supplier includes a nozzle with holes or a slit.

Methods of depositing an encapsulation stack without damaging underlying layers are discussed. The encapsulation stacks are highly conformal, have low etch rates, low atomic oxygen concentrations, good hermeticity and good adhesion. These films may be used to protect chalcogen materials in PCRAM devices. Some embodiments utilize a two-step process comprising a first ALD process to form a protective layer and a second plasma ALD process to form an encapsulation layer.

There is provided a technique that includes: (a) loading a substrate into a process container; (b) processing the substrate by supplying a processing gas into the process container to form a film containing titanium and nitrogen on the substrate; (c) unloading the processed substrate from the process container; and (d) supplying a modifying gas containing at least one selected from the group of silicon, metal, and halogen into the process container after the processed substrate is unloaded from the process container.

A deposition or cleaning apparatus including an outer vacuum chamber and a reaction chamber inside the outer chamber forming a double chamber structure. The reaction chamber is configured to move between a processing position and a lowered position inside the outer vacuum chamber, the lowered position being for loading one or more substrates into the reaction chamber

There is provided a technique, including: (a) forming NH termination on a surface of a substrate by supplying a first reactant containing N and H to the substrate; (b) forming a first SiN layer having SiCl termination formed on its surface by supplying SiCl.sub.4 as a precursor to the substrate to react the NH termination formed on the surface of the substrate with the SiCl.sub.4; (c) forming a second SiN layer having NH termination formed on its surface by supplying a second reactant containing N and H to the substrate to react the SiCl termination formed on the surface of the first SiN layer with the second reactant; and (d) forming a SiN film on the substrate by performing a cycle a predetermined number of times under a condition where the SiCl.sub.4 is not gas-phase decomposed after performing (a), the cycle including non-simultaneously performing (b) and (c).

There is provided a technique that includes a first opening and a second opening which supply gases to a process chamber in which a substrate is arranged, and is configured such that: the first opening and the second opening are arranged in a direction parallel to a surface of the substrate, a gas supplied from the first opening is supplied toward a center of the substrate, a gas supplied from the second opening is supplied toward a peripheral edge of the substrate, and a direction of the gas supplied from the second opening forms a predetermined angle with respect to a direction of the gas supplied from the first opening.

The invention relates to a substrate processing apparatus comprising a reaction chamber provided with a substrate rack for holding a plurality of substrates in the reaction chamber. The substrate rack may have a plurality of spaced apart substrate holding provisions configured to hold the plurality of substrates. The apparatus may have an illumination system constructed and arranged to irradiate radiation with a range from 100 to 500 nanometers onto a top surface of the substrates.