In one embodiment, an adapter plate for a deposition chamber is provided. The adapter plate comprises a body, a mounting plate centrally located on the body, a first annular portion extending longitudinally from a first surface of the mounting plate and disposed radially inward from an outer surface of the mounting plate, a second annular portion extending longitudinally from an opposing second surface of the mounting plate and disposed radially inward from the outer surface of the mounting plate, and a mirror-finished surface disposed on the interior of the first annular portion, the mirror-finished surface having an average surface roughness of 6 Ra or less.

A graphene synthesis chamber includes: a chamber case in which a substrate including a metal thin film is placed; a gas supply unit which supplies at least one gas comprising a carbon gas into an inner space of the chamber case; a main heating unit which emits at least one light to the inner space to heat the substrate; and at least one auxiliary heating unit which absorbs the at least one light and emits radiant heat toward the substrate.

A graphene synthesis chamber includes: a chamber case in which a substrate including a metal thin film is placed; a gas supply unit which supplies at least one gas comprising a carbon gas into an inner space of the chamber case; a main heating unit which emits at least one light to the inner space to heat the substrate; and at least one auxiliary heating unit which absorbs the at least one light and emits radiant heat toward the substrate.

The present disclosure relates to nanoscale device comprising an elongated crystalline nanostructure, such as a nanowire crystal, a nanowhisker crystal or a nanorod crystal, and a method for producing thereof. One embodiment relates to a nanoscale device comprising an elongated crystalline semiconductor nanostructure, such as a nanowire (crystal) or nanowhisker (crystal) or nanorod (crystal), having a plurality of substantially plane side facets, a crystalline structured first facet layer of a superconductor material covering at least a part of one or more of said side facets, and a second facet layer of a superconductor material covering at least a part of the first facet layer, the superconductor material of the second facet layer being different from the superconductor material of the first facet layer, wherein the crystalline structure of the semiconductor nanostructure is epitaxially matched with the crystalline structure of the first facet layer on the interface between the two crystalline structures.

A graphene synthesis chamber includes: a chamber case in which a substrate including a metal thin film is placed; a gas supply unit which supplies at least one gas comprising a carbon gas into an inner space of the chamber case; a main heating unit which emits at least one light to the inner space to heat the substrate; and at least one auxiliary heating unit which absorbs the at least one light and emits radiant heat toward the substrate.

Provided are a vapor deposition apparatus, a vapor deposition method, and a method of manufacturing an organic EL display apparatus which can prevent heat generation of a magnet chuck by using the magnet chuck that strongly attracts a deposition mask to dispose a substrate for vapor deposition and the deposition mask in proximity to each other during vapor deposition, while being less influenced by any magnetic field during alignment between the substrate for vapor deposition and the deposition mask. In the vapor deposition apparatus, a magnet chuck (3) includes a permanent magnet (3A) and an electromagnet (3B).

Provided is a ZnMg alloy plated steel material comprising: a base steel material; and first to third ZnMg alloy layers sequentially formed on the base steel material, wherein the first to third ZnMg alloy layers have a Zn single phase, a Mg single phase, a MgZn.sub.2 alloy phase, and a Mg.sub.2Zn.sub.11 alloy phase, an area rate of the MgZn.sub.2 alloy phase included in the first to third ZnMg alloy layers is larger than an area rate of the Mg.sub.2Zn.sub.11 alloy phase included in the first to third ZnMg alloy layers, and an area rate of a MgZn.sub.2 alloy phase included in each of the first to third ZnMg alloy layers is larger than an area rate of a MgZn.sub.2 alloy phase included in the second ZnMg alloy layer.

A device and a method for depositing organic layers onto a substrate includes a process gas source with a temperature-controlled evaporator, and a carrier gas supply line which opens into the evaporator in order to supply a carrier gas flow into a temperature-controlled first transport line. A first dilution gas supply line, which opens into the first transport line, supplies a dilution gas flow into the first transport line. The device also comprises a temperature-controlled gas inlet element fluidly connected to the first transport line. A gaseous starting material can be supplied into a processing chamber via the gas inlet element. A substrate is disposed on a temperature-controlled susceptor located in the processing chamber, and a layer is grown on the substrate using the gaseous starting material.

A substrate processing apparatus may be utilized, for example, for a horizontally fixed organic material deposition equipment for manufacturing large-area displays. A substrate processing apparatus may include a titanium cooling plate having an upper surface and a lower surface; an electrostatic chuck including a first dielectric layer provided on the lower surface, an electrode layer provided on the first dielectric layer, and a second dielectric layer provided on the first dielectric layer and the electrode layer, and chucking a glass substrate using an electrostatic force; and a yoke plate positioned on the upper surface and chucking a mask using a magnetic force. The titanium cooling plate may further includes a first channel provided from the upper surface, a second channel provided from the first channel, and a titanium cover plate coupled to the first channel. The titanium cooling plate may provide a cooling flow path using the second channel.

This invention relates to a coating comprising at least one AlTiN-based film deposited by means of a PVD process, wherein the at least one AlTiN-based film deposited is comprising an Al-contentin relation to the Ti-contentin atomic percentage higher than 75%, and wherein the AlTiN-based film exhibits solely a crystallographic cubic phase and internal compressive stresses and this invention relates to a method involving deposition of an AlTiN-based film.