Apparatus for physical vapor deposition are provided herein. In some embodiments, a clamp for use in a physical vapor deposition (PVD) chamber includes a clamp body and an outwardly extending shelf that extends from the clamp body, wherein the outwardly extending shelf includes a clamping surface configured to clamp an isolator ring to a chamber body of the PVD chamber, wherein a height of the outwardly extending shelf is about 15 percent to about 40 percent of a height of the clamp body and wherein the clamp body includes a central opening configured to retain a fastener therein.

Embodiments of the present disclosure disclose a physical vapor deposition (PVD) chamber and a PVD apparatus. The PVD chamber includes a chamber body. An upper electrode assembly is arranged in the chamber body. The upper electrode assembly includes a base plate assembly for carrying a magnetron, a backplate arranged at an interval with the base plate assembly, and a connection assembly that connects the base plate assembly to the backplate. The connection assembly is connected to the base plate assembly. The connection assembly is threadedly connected to the backplate, so that the interval between the base plate assembly and the backplate can be adjusted by moving the connection assembly relative to the backplate. The PVD chamber and the PVD apparatus of embodiments of the present disclosure can conveniently adjust a size of a target magnetic gap between the base plate assembly and the target according to requirements or actual conditions.

The purpose of the present invention is to improve uniformity of film deposition by a plasma-based sputtering device. Provided is a sputtering device 100 for depositing a film on a substrate W through sputtering of targets T by using plasma P, said sputtering device being provided with a vacuum chamber 2 which can be evacuated to a vacuum and into which a gas is to be introduced; a substrate holding part 3 for holding the substrate W inside the vacuum chamber 2; target holding parts 4 for holding the targets T inside the vacuum chamber 2; multiple antennas 5 which are arranged along a surface of the substrate W held by the substrate holding part 3 and generate plasma P; and a reciprocal scanning mechanism 14 for scanning back and forth the substrate holding part 3 along the arrangement direction X of the multiple antennas 5.

A magnetic shield reduces external noise in a chamber including a target and at least one electromagnet for copper physical vapor deposition (PVD). The shield may have a thickness in a range from approximately 0.1 mm to approximately 10 mm to provide sufficient protection from radio frequency and other electromagnetic signals. As a result, copper atoms in the chamber undergo less re-direction from external noise. Additionally, even when hardware failure occurs during PVD (e.g., an electromagnet malfunctions, a wafer stage is not level, and/or a flow optimizer induces too much shift, among other examples), the copper atoms are less susceptible to small re-directions from external noise. As a result, back end of line (BEOL) and/or middle end of line (MEOL) conductive structures are formed in a more uniform manner, which increases conductivity and improves lifetime of an electronic device including the BEOL and/or MEOL conductive structures.

Disclosed are embodiments for an engineered feature formed as a part of or on a chamber component. In one embodiment, a chamber component for a processing chamber includes a component part body having unitary monolithic construction. The component part body has an outer surface. An engineered complex surface is formed on the outer surface. The engineered complex surface has a first lattice framework formed from a plurality of first interconnected laths and a plurality of first openings are bounded by three or more laths of the plurality of laths.

A sputtering chamber particle trap comprises first and second patterns formed on at least a portion of a surface of the particle trap. The first pattern includes one of: first indentations having a first depth and separated by first and second threads, and first ridges having a first height and separated by first and second grooves. The second pattern is formed on at least a portion of the first pattern and includes one of: second indentations having a second depth and separated by third and fourth threads, and second ridges having a second height and separated by third and fourth grooves. A method of forming a particle trap on a sputtering chamber component is also disclosed.

A beam intensity converting film that has sufficient shielding property, sufficient durability, and sufficient heat resistance and that can reduce the extent of radioactivation. An attenuator is constituted by a graphite film placed such that a surface thereof intersects the beam axis of a charged particle beam, the graphite film has a thickness of 1 μm or greater, and the thermal conductivity in a surface direction of the graphite film is equal to or greater than 20 times the thermal conductivity in the thickness direction of the graphite film.

A sputter deposition method includes sputtering a first target material onto a web substrate moving through a first process module while heating the substrate, providing the substrate from the first process module to a connection unit containing a roller assembly including a plurality of cylindrical rollers, bending the substrate at an angle of 10° to 40° around the roller assembly in the connection unit, providing the substrate from the connection unit to a second process module, and sputtering a second target material onto the substrate moving through the second process module while heating the substrate.

Provided is a cover ring assembly that allows suppressing a dust generation source and reducing adhesion of particles on a substrate. A cover ring assembly for a substrate processing apparatus, which exposes a substrate to processing particles in an internal space to process the substrate, includes an annular flat plate and a cover ring having an annular shape. The annular flat plate has an inner peripheral upper surface and an outer peripheral upper surface. The inner peripheral upper surface is in contact with an outer peripheral lower surface terminating at an outer surface of the substrate. The outer peripheral upper surface is around the inner peripheral upper surface. The cover ring has a lower portion surface having an abutting surface in contact with the outer peripheral upper surface of the annular flat plate. A thermal spraying film covering a surface exposed to the processing particles is disposed to the cover ring except for the abutting surface.

A magnetic shield reduces external noise in a chamber including a target and at least one electromagnet for copper physical vapor deposition (PVD). The shield may have a thickness in a range from approximately 0.1 mm to approximately 10 mm to provide sufficient protection from radio frequency and other electromagnetic signals. As a result, copper atoms in the chamber undergo less re-direction from external noise. Additionally, even when hardware failure occurs during PVD (e.g., an electromagnet malfunctions, a wafer stage is not level, and/or a flow optimizer induces too much shift, among other examples), the copper atoms are less susceptible to small re-directions from external noise. As a result, back end of line (BEOL) and/or middle end of line (MEOL) conductive structures are formed in a more uniform manner, which increases conductivity and improves lifetime of an electronic device including the BEOL and/or MEOL conductive structures.