The invention provides an evaporation deposition equipment and method, applicable to vapor-depositing an organic light-emitting layer on an array substrate with a formed anode layer, the evaporation deposition equipment comprising: a first platform, disposed with an electrode plate; a second platform, disposed above the first platform, for carrying the array substrate; a vaporizing unit, disposed at the electrode plate, for generating charged vapor-depositing material particles and spraying the charged vapor-depositing material particles towards the array substrate; a mask carrier, for fixing a mask with opening pattern between the array substrate and the vaporizing unit; an electric field forming unit, electrically connected to the array substrate and the electrode plate, for forming an electric field between the anode layer and the electrode plate, the electric field guiding the charged vapor-depositing material particles towards the array substrate to deposit to form an organic light-emitting layer corresponding to the opening pattern.

A substrate carrier structure wherein the substrate may be a wafer and its use in nanoscale processes, such as deposition and/or growth processes. The carrier structure comprises grooves on its frontside and or backside.

A substrate carrier structure wherein the substrate may be a wafer and its use in nanoscale processes, such as deposition and/or growth processes. The carrier structure comprises grooves on its frontside and or backside.

A coating device that can control a coating thickness distribution along the circumferential direction of a work is provided. The coating device includes a work turning device that holds a plurality of works to rotate and revolve the works, a target having an emission face from which particles come out as a material of a coating formed on an outer circumferential face of each of the works, a power source that supplies an arc current to the target to cause the particles to come out of the target, and a controller that controls the power source to set the arc current in a particular period to be higher than a reference output, the particular period being at least a portion of a period in which a particular portion of the rotating work faces the emission face.

A coating device that can control a coating thickness distribution along the circumferential direction of a work is provided. The coating device includes a work turning device that holds a plurality of works to rotate and revolve the works, a target having an emission face from which particles come out as a material of a coating formed on an outer circumferential face of each of the works, a power source that supplies an arc current to the target to cause the particles to come out of the target, and a controller that controls the power source to set the arc current in a particular period to be higher than a reference output, the particular period being at least a portion of a period in which a particular portion of the rotating work faces the emission face.

Disclosed is a method of forming wiring of a substrate includes masking a substrate side portion, on which the wiring will be formed, by attaching a deposition mask to the substrate; and forming the wiring on the substrate side portion based on sputtering after introducing the masked substrate into a chamber.

Disclosed is a method of forming wiring of a substrate includes masking a substrate side portion, on which the wiring will be formed, by attaching a deposition mask to the substrate; and forming the wiring on the substrate side portion based on sputtering after introducing the masked substrate into a chamber.

In accordance with various embodiments, a coating arrangement may comprise: an electron beam gun for providing an electron beam; a beam trap for trapping the electron beam; a control device for driving the electron beam gun and/or the beam trap, wherein the control device is configured to switch over the driving between a plurality of configurations, of which: in a first configuration, the electron beam is directed onto the beam trap; and in a second configuration, the electron beam is directed past the beam trap.

In accordance with various embodiments, a coating arrangement may comprise: an electron beam gun for providing an electron beam; a beam trap for trapping the electron beam; a control device for driving the electron beam gun and/or the beam trap, wherein the control device is configured to switch over the driving between a plurality of configurations, of which: in a first configuration, the electron beam is directed onto the beam trap; and in a second configuration, the electron beam is directed past the beam trap.

An electrostatic chuck unit includes a first wiring portion configured to generate a relatively weak electrostatic force and a second wiring portion configured to generate a relatively strong electrostatic force.