A sputtering chamber component including a front surface, a back surface opposite the front surface, and a sputter trap formed on at least a portion of the back surface, and a coating of metallic particles formed on the sputter trap. The coating has a thickness from about 0.025 mm to about 2.54 mm (0.001 inches to about 0.1 inches) and is substantially free of impurities, and the particles of the coating are substantially diffused.

In an embodiment, a system includes: a gas distributor assembly configured to dispense gas into a chamber; and a chuck assembly configured to secure a wafer within the chamber, wherein at least one of the gas distributor assembly and the chuck assembly includes: a first portion comprising a convex protrusion, and a second portion comprising a concave opening, wherein the convex protrusion is configured to engage the concave opening.

A physical vapor deposition (PVD) system is provided. The PVD system includes a PVD chamber defining a PVD volume within which a target material of a target is deposited onto a wafer. The PVD system includes the target in the PVD chamber. The target is configured to overlie the wafer. An edge of the target extends from a first surface of the target to a second surface of the target, opposite the first surface of the target. A first portion of the edge of the target has a first surface roughness. The first portion of the edge of the target extends at most about 6 millimeters from the first surface of the target to a second portion of the edge of the target. The second portion of the edge of the target has a second surface roughness less than the first surface roughness.

A film formation device includes a target holder configured to hold a target for emitting sputtering particles in a processing space inside a processing chamber, a sputtering particle emitting part configured to emit the sputtering particles from the target, a sputtering particle shielding plate having a passage hole through which the emitted sputtering particles pass, a shielding member provided to shield the passage hole, a movement mechanism configured to move the shielding member in the horizontal direction, and a controller. The controller controls the shielding member, which has the placement portion on which a substrate is placed, to be moved in one direction of the horizontal direction, and controls the sputtering particles to be emitted from the target. The sputtering particles passed through the passage hole are deposited on the substrate.

Provided is a manufacturing method of an interior member of a plasma processing apparatus, which improves processing yield. The interior member is disposed inside a processing chamber of the plasma processing apparatus and includes, on a surface thereof, a film of a material having resistance to plasma. The manufacturing method includes: a step of moving a gun by a predetermined distance along the surface of the interior member to spray the material to form the film, and disposing a test piece having a surface having a shape simulating a surface shape of the interior member within a range of the distance within which the gun is moved and forming the film of the material on the surface of the test piece; and a step of adjusting, based on a result of detecting a crystal size of the film on the surface of the test piece and presence or absence of a residual stress or inclusion of a contaminant element, a condition of forming the film on the surface of the interior member by the gun.

The present disclosure provides a multifunction chamber having a multifunctional shutter disk. The shutter disk includes a lamp device, a DC/RF power device, and a gas line on one surface of the shutter disk. With this configuration, simplifying the chamber type is possible as the various specific, dedicated chambers such as a degas chamber, a pre-clean chamber, a CVD/PVD chamber are not required. By using the multifunctional shutter disk, the degassing function and the pre-cleaning function are provided within a single chamber. Accordingly, a separate degas chamber and a pre-clean chamber are no longer required and the overall transfer time between chambers is reduced or eliminated.

Embodiments of process kits for use in plasma process chambers are provided herein. In some embodiments, a process kit for use in a process chamber includes an annular body having an upper portion and a lower portion extending downward and radially inward from the upper portion, wherein the annular body includes an inner surface having a first segment that extends downward, a second segment that extends radially outward from the first segment, a third segment that extends downward from the second segment, a fourth segment that extends radially outward from the third segment, a fifth segment that extends downward from the fourth segment, a sixth segment that extends radially inward from the fifth segment, a seventh segment that extends downward from the sixth segment, and an eighth segment that extends radially inward from the seventh segment.

A vacuum arc source for arc evaporation of boride includes: a cathode made of at least 90 at-% of boride, in particular made of more than 98 at-% of boride; an anode, which is preferably in the shape of a disk; a body made of a material which is less preferred by arc discharge compared to the cathode, the body surrounding the cathode in such a way that during operation of the vacuum arc source, movement of an arc on an arc surface of the cathode is limited by the body. At least 90 at-% of the material of the anode is of the same chemical composition as the cathode.

A sputtering apparatus includes a base on which a substrate is mounted, an annular member disposed at an outer periphery of the base to surround a side surface and a backside of the substrate without in contact with the substrate, and an edge cover that covers an outer edge of an upper surface of the substrate mounted on the base. The annular member has a first surface facing the backside of the substrate mounted on the base with a gap, a second surface facing the side surface of the substrate mounted on the base with a gap, and a tapered surface formed at a corner portion between the first surface and the second surface.

The present disclosure provides a thin-film-deposition equipment for detecting shielding mechanism, which includes a reaction chamber, a carrier, a shielding mechanism and two distance sensors. The carrier and the shielding mechanism is partially disposed within the reaction chamber. The shielding mechanism includes two shield unit and a driver. The driver interconnects and drives the two shield units to sway in opposite directions and into an open state and a shielding state. Each of the two shield unit is disposed with a reflective surface for each of the two distance sensors to respectively project optical beams onto and detect a distances therebetween when the two shield units are operated in the shielding state, such that to confirm that the shielding mechanism is in the shielding state.