Certain examples described herein relate to a sputter deposition apparatus including a substrate holder, a target loader, a plasma source to generate a plasma, and a magnet arrangement. The substrate holder is to position a substrate in a sputter deposition zone for sputter deposition of target material from a first target to the substrate in use. The target loader is to move a second target from a target priming zone into the sputter deposition zone for sputter deposition of target material from the second target to the substrate in use. The magnet arrangement configured to confine the plasma within the apparatus to the target priming zone and the sputter deposition zone. Within the target priming zone, a respective target is exposed to the plasma in use. The sputter deposition zone provides for sputter deposition of target material.

A plasma vapor deposition (PVD) chamber used for depositing material includes an apparatus for influencing ion trajectories during deposition in an edge region of a substrate. The apparatus includes a reflector assembly that surrounds a substrate support and is configured to reflect heat to the substrate during reflowing of material deposited on the substrate and a plurality of permanent magnets embedded in the reflector assembly that are configured to influence ion trajectories on the edge region of the substrate during deposition processes, the plurality of permanent magnets are spaced symmetrically around the reflector assembly.

A versatile high throughput deposition apparatus includes a process chamber and a workpiece platform in the process chamber. The workpiece platform can hold a plurality of workpieces around a center region and to rotate the plurality of workpieces around the center region. Each of the plurality of workpieces includes a deposition surface facing the center region. A gas distribution system can distribute a vapor gas in the center region of the process chamber to deposit a material on the deposition surfaces on the plurality of workpieces. A magnetron apparatus can form a closed-loop magnetic field near the plurality of workpieces. The plurality of workpieces can be electrically biased to produce a plasma near the deposition surfaces on the plurality of workpieces.

A plasma vapor deposition (PVD) chamber used for depositing material includes an apparatus for influencing ion trajectories during deposition on a substrate. The apparatus includes at least one annular support assembly configured to be externally attached to and positioned below a substrate support pedestal and a magnetic field generator affixed to the annular support assembly and configured to radiate magnetic fields on a top surface of the substrate. The magnetic field generator may include a plurality of symmetrically spaced discrete permanent magnets or may use one or more electromagnets to generate the magnetic fields.

A plasma vapor deposition (PVD) chamber used for depositing material includes an apparatus for influencing ion trajectories during deposition on a substrate. The apparatus includes at least one annular support assembly configured to be externally attached to and positioned below a substrate support pedestal and a magnetic field generator affixed to the annular support assembly and configured to radiate magnetic fields on a top surface of the substrate. The magnetic field generator may include a plurality of symmetrically spaced discrete permanent magnets or may use one or more electromagnets to generate the magnetic fields.

A magnetic structure in a semiconductor apparatus is arranged outside of a reaction chamber of the semiconductor apparatus and includes an annular support member, a plurality of angle adjustment assemblies, and a plurality of magnetic members. The annular support member is arranged around the reaction chamber of the semiconductor apparatus. The plurality of angle adjustment assemblies are connected to the annular support member and distributed along a circumferential direction of the annular support member. The plurality of magnetic members are connected to the plurality of angle adjustment assemblies in a one-to-one correspondence. An angle adjustment assembly of the angle adjustment assemblies is configured to fix a corresponding magnetic member of the plurality of magnetic members at the annular support member and adjust a magnetic field line direction of the magnetic member and a magnitude of an included angle.

A diamond and a preparation method and use. The method for preparing diamond comprises: processing a substrate material of a substrate holder to obtain a surface that is easily separated from diamond films using a plasma chemical vapor deposition method to form a diamond film layer on the surface of the substrate holder, wherein the plasma chemical vapor deposition uses a multi-energy sources coupled plasma; post-processing the diamond film layer to remove impurity material on the diamond surface and a nucleation layer and/or stress layer with inconsistent properties of a main body of the diamond film. The method has the advantages of controllable thickness, controllable quality, controllable cost, etc., and lays the foundation for diamond in the fields of cutting tools and heat sinks.

The disclosure pertains to a capacitively coupled plasma source in which VHF power is applied through an impedance-matching coaxial resonator having a symmetrical power distribution.

In a magnetron sputtering reaction space a magnetron magnetic field is generated. A further magnetic field is generated in the reaction space whereby a resultant magnetic field has a directional component parallel to a target plane which is larger than the directional component of the magnetron magnetic field parallel to the target plane in the reaction space.

A deposition apparatus includes a shield member having a lattice shape in a plan view, the lattice shape including short side edges extending along a first direction and long side edges extending along a second direction, the short side edges including first and second short side edges, a bracket member including a first bracket member coupled to the first short side edge, and a second bracket member coupled to the second short side edge, a plurality of anode bars extending along the second direction and stably placed on each of the first bracket member and the second bracket member, and a target member covering the plurality of anode bars. An anode bar of the plurality of anode bars protrudes outward beyond at least one of the first bracket member and the second bracket member, and the anode bar is physically separated from the shield member by the bracket member.