A system and method for reducing particle contamination on substrates during a deposition process using a particle control system is disclosed here. In one embodiment, a film deposition system includes: a processing chamber sealable to create a pressurized environment and configured to contain a plasma, a target and a substrate in the pressurized environment; and a particle control unit, wherein the particle control unit is configured to provide an external force to each of at least one charged atom and at least one contamination particle in the plasma, wherein the at least one charged atom and the at last one contamination particle are generated by the target when it is in direct contact with the plasma, wherein the external force is configured to direct the at least one charged atom to a top surface of the substrate and to direct the at least one contamination particle away from the top surface of the substrate.

A transparent structure may have multiple layers, such as an inner layer and an outer layer, which may be formed from glass. The transparent structure may have a large, curved surface with compound curvature and high geometric strain and may include one or more layers. To apply a physical vapor deposition coating with uniform thickness on a curved surface, cathode power may be modulated during the deposition, a mask having an opening with a curvature matching the curved surface may be used, a cathode shape may be varied, the cathodes may sputter the coating outwardly toward the curved surface, a magnetic field may modulate the flux produced by the cathodes, and/or the pressure and/or flow of gas may be adjusted. By modifying the physical vapor deposition coater in one or more of these ways, the coating may have a uniform thickness, and therefore a uniform color, across the curved surface.

A high current density plasma generator includes a chamber that contains a feed gas. An anode is positioned in the chamber. A cathode assembly is position adjacent to the anode inside the chamber. A power supply having an output is electrically connected between the anode and the cathode assembly. The power supply generates at the output an oscillating voltage that produces a plasma from the feed gas. At least one of an amplitude, frequency, rise time, and fall time of the oscillatory voltage is chosen to increase an ionization rate of the feed gas.

ZnO sputtering is performed while a rolling body is housed in a basket made of a metal wire and is rotated. By setting a ratio of a mesh size of the basket to a diameter of the rolling body in a range of 40 to 95%, fine and uniform ZnO coating can be formed on a surface of the rolling body. By using the rolling body with ZnO coating prepared in this manner in a bearing which is rotated at high speed in a high-load state, a friction coefficient can significantly be lowered in comparison with a case of no coating.

An ionized physical vapor deposition (I-PVD) source includes an electrically and magnetically enhanced radio frequency (RF) diode, which has magnetic field lines directed substantially perpendicular to a cathode that terminate on an electrode positioned between an anode around the cathode. The anode forms a gap and the electrode is positioned behind the gap. An RF power supply connected to the cathode generates RF discharge. The cathode is inductively grounded to prevent forming a constant voltage bias during RF discharge. The electrons drift between the cathode and the gap, thereby producing ionization and forming high density plasma. The electrons drift and energy are controlled by applying different voltage potentials to the electrode. The I-PVD source is positioned in a vacuum chamber to form an I-PVD apparatus that generates ions from sputtered target material atoms and deposition. During sputtering, the substrate is biased. The I-PVD source performs chemically enhanced ionized physical vapor deposition (CE-IPVD).

Systems and methods provide a solution for efficiently generating high density plasma for a physical vapor deposition (PVD). The present solution includes a vacuum chamber for a PVD process. The system can include a target located within the vacuum chamber for sputtering a material onto a wafer. The system can include a resonant structure formed by an antenna and a plurality of capacitors. The resonant structure can be configured to provide a pulsed output at a resonant frequency. The resonant structure can be configured to generate, via the antenna and based on the pulsed output, a plasma between the target and a location of the wafer to ionize the material sputtered from the target.

A physical vapor deposition (PVD) system is disclosed. The PVD system includes a pedestal configured to hold a semiconductor wafer, a cover plate configured to hold a target, and a collimator between the pedestal and the cover plate. The collimator includes a plurality of passages configured to pass source material travelling from the cover plate toward the pedestal at an angle less than a threshold angle with respect to a line perpendicular to a surface of the pedestal facing the cover plate, where the collimator is configured to block source material travelling from the cover plate toward the pedestal at an angle greater than the threshold angle, where a first passage of the plurality of passages has a first passage length, where a second passage of the plurality of passages has a second passage length, and where the first passage length is less than the second passage length.

An electrically and magnetically enhanced ionized physical vapor deposition (I-PVD) magnetron apparatus and method is provided for sputtering material from a cathode target on a substrate, and in particular, for sputtering ceramic and diamond-like coatings. The electrically and magnetically enhanced magnetron sputtering source has unbalanced magnetic fields that couple the cathode target and additional electrode together. The additional electrode is electrically isolated from ground and connected to a power supply that can generate positive, negative, or bipolar high frequency voltages, and is preferably a radio frequency (RF) power supply. RF discharge near the additional electrode increases plasma density and a degree of ionization of sputtered material atoms.

A magnetically enhanced HDP-CVD plasma source includes a hollow cathode target and an anode. The anode and cathode form a gap. A cathode target magnet assembly forms magnetic field lines that are substantially perpendicular to a cathode target surface. The gap magnet assembly forms a cusp magnetic field in the gap that is coupled with the cathode target magnetic field. The magnetic field lines cross a pole piece electrode positioned in the gap. This pole piece is isolated from ground and can be connected with a voltage power supply. The pole piece can have a negative, positive, or floating electric potential. The plasma source can be configured to generate volume discharge. The gap size prohibits generation of plasma discharge in the gap. By controlling the duration, value and a sign of the electric potential on the pole piece, the plasma ionization can be controlled. The magnetically enhanced HDP-CVD source can also be used for chemically enhanced ionized physical vapor deposition (CE-IPVD). Gas flows through the gap between hollow cathode and anode. The cathode target is inductively grounded, and the substrate is periodically inductively grounded.

A magnetically enhanced low temperature high density plasma chemical vapor deposition (LT-HDP-CVD) source has a hollow cathode target and an anode, which form a gap. A cathode target magnet assembly forms magnetic field lines substantially perpendicular to the cathode surface. A gap magnet assembly forms a magnetic field in the gap that is coupled with the cathode target magnetic field. The magnetic field lines cross the pole piece electrode positioned in the gap. The pole piece is isolated from ground and can be connected to a voltage power supply. The pole piece can have negative, positive, floating, or RF electrical potentials. By controlling the duration, value, and sign of the electric potential on the pole piece, plasma ionization can be controlled. Feed gas flows through the gap between the hollow cathode and anode. The cathode can be connected to a pulse power or RF power supply, or cathode can be connected to both power supplies. The cathode target and substrate can be inductively grounded.