A linear evaporation source includes: a crucible accommodating an evaporation material; a heating unit enclosing the crucible and heating the crucible; and a nozzle unit above the crucible, the nozzle unit including a nozzle plate and at least one nozzle protruding from the nozzle plate. A length of the crucible is about 5 times to about 30 times greater than a width of the crucible. The crucible includes molybdenum (Mo) in an amount of about 95.0 percentage by weight (wt %) to about 99.99 wt % and lanthanum oxide (La.sub.2O.sub.3) in an amount of about 0.01 wt % to about 5 wt %, with respect to the total weight of the crucible.

Embodiments of the present disclosure provides apparatus and method for stabilizing substrate temperature by flowing a flow of cooling gas to an inlet of cooling channels in a substrate support, receiving the flow of cooling gas from an outlet of the cooling channel using a heat exchanger, and releasing the cooling gas to an immediate environment, such as a cleanroom or a minienvironment.

Embodiments of the present disclosure provides apparatus and method for stabilizing substrate temperature by flowing a flow of cooling gas to an inlet of cooling channels in a substrate support, receiving the flow of cooling gas from an outlet of the cooling channel using a heat exchanger, and releasing the cooling gas to an immediate environment, such as a cleanroom or a minienvironment.

A holding arrangement for supporting a substrate carrier and a mask carrier during layer deposition in a processing chamber is provided. The holding arrangement includes two or more alignment actuators connectable to at least one of the substrate carrier and the mask carrier, wherein the holding arrangement is configured to support the substrate carrier in, or parallel to, a first plane, wherein a first alignment actuator of the two or more alignment actuators is configured to move the substrate carrier and the mask carrier relative to each other at least in a first direction, wherein a second alignment actuator of the two or more alignment actuators is configured to move the substrate carrier and the mask carrier relative to each other at least in the first direction and a second direction different from the first direction, and wherein the first direction and the second direction are in the first plane.

A holding arrangement for supporting a substrate carrier and a mask carrier during layer deposition in a processing chamber is provided. The holding arrangement includes two or more alignment actuators connectable to at least one of the substrate carrier and the mask carrier, wherein the holding arrangement is configured to support the substrate carrier in, or parallel to, a first plane, wherein a first alignment actuator of the two or more alignment actuators is configured to move the substrate carrier and the mask carrier relative to each other at least in a first direction, wherein a second alignment actuator of the two or more alignment actuators is configured to move the substrate carrier and the mask carrier relative to each other at least in the first direction and a second direction different from the first direction, and wherein the first direction and the second direction are in the first plane.

An evaporation method and an evaporation device for an organic light-emitting diode substrate are proposed. The evaporation method includes: step 1, regulating a distance between a supporting module for supporting a substrate and a crucible platform of an evaporation device; step 2, adjusting a direction of opening of a crucible disposed on the crucible platform; and step 3, placing a substrate to be evaporated on the supporting module and volatizing an evaporation source in the crucible and attaching the volatized evaporation source onto a surface of the substrate.

An evaporation method and an evaporation device for an organic light-emitting diode substrate are proposed. The evaporation method includes: step 1, regulating a distance between a supporting module for supporting a substrate and a crucible platform of an evaporation device; step 2, adjusting a direction of opening of a crucible disposed on the crucible platform; and step 3, placing a substrate to be evaporated on the supporting module and volatizing an evaporation source in the crucible and attaching the volatized evaporation source onto a surface of the substrate.

According to one embodiment, an apparatus of manufacturing a radiation detection panel, includes an evaporation source configured to evaporate a scintillator material and emit the scintillator material vertically upward, a holding mechanism located vertically above the evaporation source, and holding a photoelectric conversion substrate, and a heat conductor arranged opposite to the holding mechanism with a gap.

Pedestal assemblies with a thermal barrier plate, a torque plate and at least one kinematic mount to change a plane formed by the thermal barrier plate are described. Susceptor assemblies and processing chambers incorporating the pedestal assemblies are also described. Methods of leveling a susceptor to form parallel planes between the susceptor surface and a gas distribution assembly surface are also described.

This deposition apparatus includes a deposition chamber which includes a deposition region for forming a coating film on an object to be coated, a conveying device which conveys a conveyed carrier supporting the object, and a bias power source which applies a bias voltage to the object via the conveyed carrier, in which a plurality of rods which support the object and rotate around axes are disposed in the conveyed carrier along a carrier conveying direction in an upright posture, a protrusion member protruding to the outside in a radial direction is provided on an outer peripheral surface of the rod, an interference member which catches the protrusion member of the conveyed carrier moving in the deposition chamber and rotates the rod around the axis is provided on a wall surface of the deposition chamber, and the interference member and the bias power source are electrically connected to each other.