The present disclosure provides an improvement to razor blade coating by a physical vapor deposition method, by forming a hard coating layer as a thin coating layer in which chromium boride, which is a nanocrystalline structure having high hardness, is dispersed in an amorphous mixture of chromium and boron, thereby improving the strength and hardness of the thin coating layer and securing the bonding force by chromium in the amorphous mixture between the hard coating layer and a blade substrate on which an edge of the razor blade is formed.

A sputter deposition apparatus including: a plasma generation arrangement arranged to provide single plasma for sputter deposition of target material within a sputter deposition zone; a conveyor system arranged to convey a substrate through the sputter deposition zone in a conveyance direction; and one or more target support assemblies arranged to support one or more targets in the sputter deposition zone so as to provide for sputter deposition of the target material on the substrate utilising the plasma such that as the substrate is conveyed through the sputter deposition zone in use there is deposited: a first stripe on the substrate; and a second stripe on the substrate. The first stripe includes at least one of: a different density of the target material or a different composition of the target material than the second stripe.

A deposition system is provided for guiding a flexible substrate along a deposition path. The deposition system includes a payout hub for unwinding the flexible substrate; a pickup hub for winding the flexible substrate; one or more evaporation sources (300); one or more electrodes (510) spaced apart from the one or more evaporation sources in a first direction; one or more measurement devices (550); and a controller (601) configured to adjust one or more voltages provided to the one more electrodes.

In a method for coating a base body, a first target and a second target are arranged in a vacuum chamber. A base body to be coated is arranged in the vacuum chamber is heated to a coating temperature of less than 600° C. During sputtering with sputter gas ions, first target particles are liberated from the first target and second target particles are liberated from the second target and are deposited as coating particles on the base body. A first sputter rate is specified for the first target and a second sputter rate is specified for the second target such that, during the sputtering process, the coating is generated as an A15 phase with an intended stoichiometric ratio of the first target particles to the second target particles. A functional element has a base body and a coating of Nb.sub.3Sn applied directly on the surface of the base body.

A coated cutting tool and a process for the production thereof id provided. The coated cutting tool consists of a substrate body of WC-Co based cemented carbide and a coating, the coating including a first (Ti,Al)N multilayer, a first gamma-aluminium oxide layer, and a set of alternating second (Ti,Al)N multilayers and second gamma-aluminium oxide layers.

A method is provided. The method includes the following steps: introducing a first physical vapor deposition (PVD) target and a second PVD target in a PVD system, the first PVD target containing a boron-containing cobalt iron alloy (FeCoB) with an initial boron concentration, and the second PVD target containing boron; determining parameters of the PVD system based on a target boron concentration larger than the initial boron concentration; and depositing a FeCoB film on a substrate according to the parameters of the PVD system.

The present invention relates to a method of forming a coating layer of which a composition can be controlled, the method comprising steps of: preparing a substrate inside a chamber; evaporating a deposition material to generate YF.sub.3 or YOF particles in a gas phase by irradiating an electron beam on a YF.sub.3 deposition material provided in a solid form in an electron beam source; generating radical particles having activation energy by injecting a process gas containing oxygen into a RF energy beam source; irradiating an RF energy beam including oxygen radical particles toward the substrate; controlling a composition of a thin film by generating YOF deposition particles having a modified atomic ratio by adjusting an amount of fluorine substitution by oxygen as the YF.sub.3 or YOF particles and the oxygen radical particles react, and depositing the YOF deposition particles on the substrate with the RF energy beam.

The color of an electrochromic stack in a tinted state may be modified to achieve a desired color target by utilizing various techniques alone or in combination. A first approach generally involves changing a coloration efficiency of a WO.sub.x electrochromic (EC) layer by lowering a sputter temperature to achieve a WO.sub.x microstructural change in the EC layer. A second approach generally involves utilizing a dopant (e.g., Mo, Nb, or V) to improve the neutrality of the tinted state of WO.sub.x (coloration efficiency changes). A third approach generally involves tailoring a thickness of the WO.sub.x layer to tune the color of the tinted stack.

The present disclosure provides a razor blade coating by a physical vapor deposition method through performing a deposition with a single composite target composed of dissimilar materials with their area ratio defined to be varied in the single composite target in the direction of transferring the razor blade subject to the deposition, thereby forming a single layer in which the composition ratio of the dissimilar materials gradually changes in the thickness direction of the coating layer to improve the durability of the razor blade coating layer.

Apparatus for depositing germanium and carbon onto one or more substrates comprises a vacuum chamber, at least first and second magnetron sputtering devices and at least one movable mount for supporting the one or more substrates within the vacuum chamber. The first magnetron sputtering device is configured to sputter germanium towards the at least one mount from a first sputtering target comprising germanium, thereby defining a germanium sputtering zone within the vacuum chamber. The second magnetron sputtering device is configured to sputter carbon towards the at least one mount from a second sputtering target comprising carbon, thereby defining a carbon sputtering zone within the vacuum chamber. The at least one mount and the at least first and second magnetron sputtering devices are arranged such that, when each substrate is moved through the germanium sputtering zone on the at least one movable mount, germanium is deposited on the said substrate, and when each substrate is moved through the carbon sputtering zone on the at least one movable mount, carbon is deposited on the said substrate.