Physical vapor deposition target assemblies and methods of manufacturing such target assemblies are disclosed. An exemplary target assembly comprises a flow pattern including a plurality of arcs and bends fluidly connected to an inlet end and an outlet end.

Physical vapor deposition target assemblies and methods of manufacturing such target assemblies are disclosed. An exemplary target assembly comprises a flow pattern including a plurality of arcs and bends fluidly connected to an inlet end and an outlet end.

Disclosed are an apparatus for and a method of manufacturing a semiconductor device. The apparatus includes a chamber, an evaporator that evaporates an organic source to provide a source gas on a substrate in the chamber, a vacuum pump that pumps the source gas and air from the chamber, an exhaust line between the vacuum pump and the chamber, and an analyzer connected to the exhaust line. The analyzer detects a derived molecule produced from the organic source and determines a replacement time of the evaporator.

Embodiments of the disclosure generally relate to methods of forming gratings. The method includes depositing a resist material on a grating material disposed over a substrate, patterning the resist material into a resist layer, projecting a first ion beam to the first device area to form a first plurality of gratings, and projecting a second ion beam to the second device area to form a second plurality of gratings. Using a patterned resist layer allows for projecting an ion beam over a large area, which is often easier than focusing the ion beam in a specific area.

A substrate fixing device according to the present invention is a substrate fixing device configured to fix a substrate so that a deposition material evaporated from at least one evaporation source is deposited on the substrate. The substrate fixing device includes a substrate temperature adjustment part configured to transfer heat to the substrate, and a substrate fixing part coupled to one side of the substrate temperature adjustment part and configured to fix the substrate, in which the substrate fixing part fixes the substrate so that a front surface of the substrate is exposed in a direction toward the evaporation source, and in which a space is formed between the substrate fixing part and a rear surface of the substrate.

Exemplary semiconductor processing systems may include a chamber body having sidewalls and a base. The semiconductor processing systems may include a substrate support extending through the base of the chamber body. The substrate support may include a support plate. The substrates support may include a shaft coupled with the support plate. The semiconductor processing systems may include a liner positioned within the chamber body and positioned radially outward of a peripheral edge of the support plate. An inner surface of the liner may include an emissivity texture.

Multi-layer metal or pseudometallic materials having engineered anisotropy are disclosed. The multi-layer materials having defined engineered grain orientations in each layer of the multi-layer material and bond layers between adjacent layers orthogonal to the grain orientations. This configuration distributes applied stress across the plurality of layers in the multi-layer metal material and around a neutral axis of the multi-layer metal material and increases the overall mechanical properties of the disclosed multi-layer metal material relative to conventional wrought metal materials of the same or similar chemical constitution. The microstructure of each layer, group of layers, or across multiple layers may be tailored to the intended application of a device made from the material. Individual layers may be tuned for property variations, such as gradients, or to adjust the bond layer characteristics. A method of making the multi-layer metal materials by physical vapor deposition to deposit each layer as crystalline grain structures and allow for layer-by-layer control over the physical, mechanical and chemical properties of each layer in the multi-layer metal as well as a bond layer between adjacent layers is disclosed.

Methods and systems for the delivery of molten metals and metal alloys at a fixed volume are provided. The system includes an evaporation system having a fluid inlet port and a fluid delivery system. The fluid delivery system includes an ampoule operable to hold a source material. The ampoule includes a fluid outlet port and a gas inlet port. The fluid delivery system further includes a fluid delivery line operable to deliver the source material to the evaporation system. The fluid delivery line includes a first end fluidly coupled with the fluid outlet port and a second end fluidly coupled to the fluid inlet port. The fluid delivery line further includes a first isolation valve disposed along the fluid delivery line and a second isolation valve disposed along the fluid delivery line which define a fixed volume of the fluid delivery line.

Methods and systems for the delivery of molten metals and metal alloys at a fixed volume are provided. The system includes an evaporation system having a fluid inlet port and a fluid delivery system. The fluid delivery system includes an ampoule operable to hold a source material. The ampoule includes a fluid outlet port and a gas inlet port. The fluid delivery system further includes a fluid delivery line operable to deliver the source material to the evaporation system. The fluid delivery line includes a first end fluidly coupled with the fluid outlet port and a second end fluidly coupled to the fluid inlet port. The fluid delivery line further includes a first isolation valve disposed along the fluid delivery line and a second isolation valve disposed along the fluid delivery line which define a fixed volume of the fluid delivery line.

An apparatus for contactless transportation of a device in a vacuum processing system is described. The apparatus includes: a magnetic transportation arrangement for providing a magnetic levitation force (F.sub.L) for levitating the device, the magnetic transportation arrangement comprising one or more active magnetic units; a sensor for monitoring a motion of the device, and a controller configured for controlling the one or more active magnetic units based on a signal provided by the sensor.