One or more embodiments described herein generally relate to methods and systems for monitoring film thickness using a sensor assembly. In embodiments described herein, a process chamber having a chamber body, a substrate support disposed in the chamber body, a lid disposed over the chamber body, and a sensor assembly coupled to the chamber body at a lower portion of the sensor assembly. The sensor assembly is coupled to the lid at an upper portion of the sensor assembly. The sensor assembly includes one or more apertures disposed through one or more sides of the sensor assembly, and the one or more sensors are disposed in the sensor assembly through the one or more of the apertures.

A film thickness control system and a film thickness control method for an evaporation device, an evaporation device and an evaporation method are disclosed. The film thickness control system includes: a driving device, a film thickness meter and a computer; the film thickness meter is mounted on the driving device, connected with the computer, and configured to acquire a coordinate of a measured position of a substrate to be measured from the computer and send an actual film thickness of the measured position to the computer; and the computer is configured, when the actual film thickness does not exceed an error range of a preset film thickness, to calculate a new compensation value according to the actual film thickness, the preset film thickness and a current compensation value, and send the new compensation value to the evaporation device as reference for compensating evaporation.

The present disclosure relates to the field of display technology, particularly to a vacuum deposition apparatus and a vapor deposition method. The vacuum deposition apparatus includes a vacuum chamber and a rotary base, an evaporation source, and a plurality of vapor deposition zones arranged in series from bottom to top in the vacuum chamber, wherein the shape of the rotary base is a Reuleaux triangle, and the trajectories of movement of its vertices in the horizontal plane is a rounded square, the vapor deposition zones are arranged at intervals along the trajectories of movement of the vertices of the rotary base, the evaporation source is driven by the rotary base to pass below the vapor deposition zones sequentially, so that the evaporation source can be used to perform the vapor deposition operation in multiple directions simultaneously, thus improving the uniformity of film formation and utilization of the evaporation material.

A measuring assembly and method for layer thickness measurement of a layer applied to a substrate by means of a vapor deposition method includes a measuring head which is provided with at least one vibration plate, an extraction line which can be coupled in a gas-conducting or vapor-conducting manner with a first end having a vacuum chamber for the vapor deposition method and which can be coupled in a gas-conducting or vapor-conducting manner with an opposite second end having the measuring head, wherein the extraction line includes at least one heating section or at least one cooling section.

Methods and systems for monitoring film thickness using a sensor assembly include a process chamber having a chamber body, a substrate support disposed in the chamber body, a lid disposed over the chamber body, and a sensor assembly coupled to the chamber body at a lower portion of the sensor assembly. The sensor assembly is coupled to the lid at an upper portion of the sensor assembly. The sensor assembly includes one or more apertures disposed through one or more sides of the sensor assembly, and the one or more sensors are disposed in the sensor assembly through the one or more of the apertures.

Devices, systems and methods for process monitoring are presented. For instance, the device includes a crystal and a reactance sensor. The crystal is connected to a frequency measurement circuit. The reactance sensor is connected to the crystal. The reactance sensor is configured to detect a change in a process parameter. The frequency measurement circuit detects the change in the process parameter as a change in the frequency of the crystal. In another example, the system includes a reactance sensor and a measurement device. The reactance sensor is disposed in a process chamber, and has a variable reactance responsive to a change in a process parameter. The measurement device is disposed outside the process chamber and has a frequency measurement circuit. The frequency measurement circuit includes a crystal and is connected to the reactance sensor, and detects the change in the process parameter as a change in the frequency of the crystal.

Striated composite layers are deposited using reactive electron-beam evaporation of hafnium dioxide and silicon dioxide sublayers in a planetary rotation or linear translation system in which the hafnia and silica vapor plumes are present at the same time, and yet the hafnia and silica sublayers are distinct. The resulting StriCom materials exhibit significant improvements in laser-induced damage thresholds, thin-film stresses, environmental sensitivity, and control of refractive indices relative to monolayer hafnia films.

A crystal oscillation probe structure and an evaporation device are provided. The crystal oscillation probe structure includes a guide cover, a crystal oscillation probe and a mesh screen structure, the guide cover includes a chamber with a guide opening, the crystal oscillation probe is fixed in the chamber, the crystal oscillation probe includes at least one crystal oscillation sheet, the mesh screen structure includes a plurality of openings, and the mesh screen structure is located on a traveling path of a material traveling toward the at least one crystal oscillation sheet and disposed on a side of the at least one crystal oscillation sheet facing the guide opening.

The invention relates to an optical article provided with antireflection properties, comprising a substrate having at least one main surface coated with an antireflection coating comprising, starting from the substrate: a sub-layer comprising two adjacent layers formed from the same material, the sum of the thicknesses of the two adjacent layers being greater than or equal to 75 nm; and a multilayered antireflection stack comprising at least one high refractive index layer and at least one low refractive index layer, the deposition of the first of said two adjacent layers of the sub-layer having been carried out without ion assistance and the deposition of the second of said two adjacent layers of the sub-layer having been carried out under ion assistance. The invention also relates to a process for manufacturing such an optical article.

The present invention relates to methods of forming a film between two surfaces, in which the film includes diamond-like carbon. Also provided herein are uses of such films, such in sliding contacts and in metal coatings.