The present disclosure relates to plasma generation systems particularly applicable to systems which utilize plasma for semiconductor processing. A plasma generation system consistent with the present disclosure includes an arc suppression device coupled to the RF generator. The arc device includes switches that engage upon a triggering signal. In addition, the arc device includes a power dissipater to be engaged by the set of switches to dissipate both stored and delivered energy when the set of switches engage. The arc suppression device also includes an impedance transformer coupled to the power dissipater to perform an impedance transformation that, when the switches are engaged in conjunction with the power dissipater, reduces the reflection coefficient at the input of the device. The plasma generation system further includes a matching network coupled to the radio frequency generator and a plasma chamber coupled to the matching network.

The present disclosure relates to plasma generation systems particularly applicable to systems which utilize plasma for semiconductor processing. A plasma generation system consistent with the present disclosure includes an arc suppression device coupled to the RF generator. The arc device includes switches that engage upon a triggering signal. In addition, the arc device includes a power dissipater to be engaged by the set of switches to dissipate both stored and delivered energy when the set of switches engage. The arc suppression device also includes an impedance transformer coupled to the power dissipater to perform an impedance transformation that, when the switches are engaged in conjunction with the power dissipater, reduces the reflection coefficient at the input of the device. The plasma generation system further includes a matching network coupled to the radio frequency generator and a plasma chamber coupled to the matching network.

An AC power connector for connecting an AC power supply with a device is provided. The AC power connector includes at least one first element connectable with the AC power supply and at least one second element connectable with the device, the first element and the second elements being arranged at a first distance with respect to each other for defining a capacitance, wherein the at least one first element and the at least one second element are rotatable with respect to each other, wherein the first element and the second element are configured for a transfer of an AC power between the at least one first element and the at least one second element.

A reactor includes a plasma duct; a gas inlet, at a distal end of the plasma duct, for receiving a gas; a gas outlet at a proximal end of the plasma duct for removing a portion of the gas to generate a gas flow through the plasma duct; a separating baffle positioned between the plasma duct and the gas outlet for restricting gas flow to maintain high pressure in the plasma duct; a shielded cathodic arc source positioned in a cathode chamber at the proximal end; a remote anode, positioned in the plasma duct, for holding a substrate and cooperating with the cathodic arc source to generate an electron flow opposite the gas flow, to initiate a plasma discharge perpendicular to the remote anode at least in vicinity of the remote anode and deposit ions of the plasma discharge on the substrate to form a diamond coating.

Techniques are disclosed for methods and apparatuses for reducing particle contamination formation in a high temperature processing chamber with a cooled gas feed block. The cooled gas feed has a body. The body has a main center portion having a top surface and a bottom surface. The body also has a flange extending outward from the bottom surface of the main center portion. A gas channel is disposed through the body. The gas channel has an inlet formed in the top surface of the main center portion and an outlet formed in the bottom surface of the main center portion. The body also has a center coolant channel. The center coolant channel has a first portion having an inlet formed in the top surface of the main center portion, and a second portion coupled to the first portion, the second portion having an outlet formed a sidewall of the flange.

A method for manufacturing a sputtering target with which an oxide semiconductor film with a small amount of defects can be formed is provided. Alternatively, an oxide semiconductor film with a small amount of defects is formed. A method for manufacturing a sputtering target is provided, which includes the steps of: forming a polycrystalline In-M-Zn oxide (M represents a metal chosen among aluminum, titanium, gallium, yttrium, zirconium, lanthanum, cesium, neodymium, and hafnium) powder by mixing, sintering, and grinding indium oxide, an oxide of the metal, and zinc oxide; forming a mixture by mixing the polycrystalline In-M-Zn oxide powder and a zinc oxide powder; forming a compact by compacting the mixture; and sintering the compact.

A film forming device includes an adhesion preventing mechanism in a film formation chamber, in which the adhesion preventing mechanism is configured with a plurality of adhesion preventing plates including at least a substrate edge adhesion preventing plate that is provided on an edge of a region on the substrate holding portion where the substrate is provided and a substrate outer peripheral region adhesion preventing plate that is disposed on an outer periphery of the substrate edge adhesion preventing plate to be spaced from the substrate edge adhesion preventing plate, a potential adjusting mechanism that is electrically connected to any one of the substrate edge adhesion preventing plate or the substrate outer peripheral region adhesion preventing plate is provided, and the adhesion preventing plate connected to the potential adjusting mechanism and an adhesion preventing plate disposed adjacent thereto are disposed at an interval of 0.5 mm to 3.0 mm.

A method for manufacturing a sputtering target with which an oxide semiconductor film with a small amount of defects can be formed is provided. Alternatively, an oxide semiconductor film with a small amount of defects is formed. A method for manufacturing a sputtering target is provided, which includes the steps of: forming a polycrystalline In-M-Zn oxide (M represents a metal chosen among aluminum, titanium, gallium, yttrium, zirconium, lanthanum, cesium, neodymium, and hafnium) powder by mixing, sintering, and grinding indium oxide, an oxide of the metal, and zinc oxide; forming a mixture by mixing the polycrystalline In-M-Zn oxide powder and a zinc oxide powder; forming a compact by compacting the mixture; and sintering the compact.

A method and system for plasma arc suppression includes a RF generator supplying power to a plasma chamber coupled to an impedance matching network reacting to impedance changes to match an impedance of the plasma chamber with an impedance of the radio frequency generator. An arc suppression device coupled to the RF generator and the plasma chamber detects plasma arcing causing a sharp impedance change increasing reflection of the power by the plasma chamber and switches a power dissipator reducing the power delivered to the plasma chamber extinguishing or mitigating the plasma arcing. The power dissipator is switched more quickly than the impedance matching network reacts to the sharp impedance change. For example, the impedance matching network may react to the impedance change on an order of hundredths of milliseconds or more, while the arc suppression device switches the power dissipator on an order of microseconds or less.

A method for manufacturing a sputtering target with which an oxide semiconductor film with a small amount of defects can be formed is provided. Alternatively, an oxide semiconductor film with a small amount of defects is formed. A method for manufacturing a sputtering target is provided, which includes the steps of: forming a polycrystalline In-M-Zn oxide (M represents a metal chosen among aluminum, titanium, gallium, yttrium, zirconium, lanthanum, cesium, neodymium, and hafnium) powder by mixing, sintering, and grinding indium oxide, an oxide of the metal, and zinc oxide; forming a mixture by mixing the polycrystalline In-M-Zn oxide powder and a zinc oxide powder; forming a compact by compacting the mixture; and sintering the compact.