The present application discloses a new type of deposition source, where individual sources are placed in a substantial closed loop. The closed polygon deposition sources have no end in circumference and enable better deposition uniformity. A closed loop deposition sources minimize the edge effects in sputtering, chemical vapor deposition (CVD) and plasma enhanced chemical vapor deposition (PECVD) and increase deposition material utilization.

A plasma processing system used for reactive sputtering may include multiple dual magnetron sputtering (DMS) components. Each DMS component may include a power supply coupled with two electrodes that switch between operation as a cathode and anode and are located within a plasma chamber. The power supply may be configured to operate as a transmitter or receiver power supply. A transmitter power supply may receive a phase-control-input signal that includes a phase offset value and may produce a phase-control-output signal and synchronization signal. The transmitter power supply may send the phase-control-output signal and synchronization signal to a receiver power supply, which may use these signals to synchronize electrode switching with the transmitter power supply and to apply the phase offset.

Methods and apparatus for forming a thin film transistor (TFT) having a metal oxide layer. The method may include forming an amorphous metal oxide layer and treating the metal oxide layer with a silicon containing gas or plasma including Si.sup.4+ ions. The silicon treatment of the metal oxide layer helps fill the oxygen vacancies in the metal oxide channel layer, leading to a more stable TFT and preventing a negative threshold voltage in the TFT.

Embodiments of method for igniting a plasma are provided herein. In some embodiments, a method for igniting a plasma includes: flowing a process gas into a process chamber to increase a pressure within the process chamber to a first pressure; applying a first bias voltage from a collimator power source to a collimator disposed within the process chamber; and applying a second power to a sputtering source disposed in the process chamber above the collimator after the first pressure has been reached and the first bias voltage is applied to ignite the plasma.

A sputtering device to sputter a liquid target. The sputtering device including a trough to receive a liquid target material and a device to stir or agitate the liquid target material. The device configured to degas the liquid target material or/and to dissipate solid particles or islands on a surface of the target or/and to move such particles or islands from an active surface region to a passive surface region and/or vice-versa, whereby the passive surface region is at least 50% less exposed to sputtering as the active surface region.

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.

The invention relates to the proposal of an electrode arrangement in a device for carrying out processes of physical vapor deposition that greatly reduces or even prevents the degradation of the electrode material caused by accretions. The contamination of the anode occurring in these processes due to cathodic carbon is minimized or prevented by the application of a thin adhesion-reducing coating of high electrical conductivity to the anode, which coating has poorer adhesive properties with regard to the coating material than the uncoated anode material. This coating is preferably a nitride coating, particularly preferably of TiN, applied with a coating thickness of between 0.1 μm and 3.5 μm.

A magnetron plasma apparatus boosted by hollow cathode plasma includes at least one electrically connected pair of a first hollow cathode plate and a second hollow cathode plate placed opposite to each other at a separation distance of at least 0.1 mm and having an opening following an outer edge of a sputter erosion zone on a magnetron target so that a magnetron magnetic field forms a perpendicular magnetic component inside a hollow cathode slit between plates and, wherein the plates and are connected to a first electric power generator together with the magnetron target to generate a magnetically enhanced hollow cathode plasma in at least one of a first working gas distributed in the hollow cathode slit and a second working gas admitted outside the slit in contact with a magnetron plasma generated in at least one of the first working gas and the second working gas.

The sputtering cathode has a tubular shape having a pair of long sides facing each other in cross-sectional shape, has a sputtering target whose erosion surface faces inward, and a magnetic circuit is provided along the sputtering target. The pair of long sides are constituted by rotary targets each having a cylindrical shape. The rotary target is internally provided with a magnetic circuit and configured to allow the flow of cooling water. The magnetic circuit is provided parallel to the central axis of the rotary target and has a rectangular cross-sectional shape having a long side perpendicular to the radial direction of the rotary target.

A method for producing an optical element (2), in particular for a projection exposure system (400), according to which a protective layer (11) consisting of a protective material is applied to a surface of a main body (7) until a protective layer thickness is obtained. The main body (7) has a substrate (17) and a reflective layer (18) applied to the substrate (17). The protective layer (11) is at least substantially defect-free.