Disclosed herein are apparatuses and systems for reentrant fluid delivery techniques. An example system includes at least a fluid delivery conduit extending between first and second electrical potentials, wherein the fluid delivery conduit is formed into a tilted helical so that a fluid flowing through the fluid delivery conduit experiences an electric field reversal through each winding of the fluid delivery conduit.

In order to provide an ion beam apparatus excellent in safety and stability even when a sample is irradiated with hydrogen ions, the ion beam apparatus includes a vacuum chamber, a gas field ion source that is installed in the vacuum chamber and has an emitter tip, and gas supply means for supplying a gas to the emitter tip. The gas supply means includes a mixed gas chamber that is filled with a hydrogen gas and a gas for diluting the hydrogen gas below an explosive lower limit.

Some embodiments provide a magnetron sputtering apparatus including a vacuum chamber within which a controlled environment may be established, a target comprising one or more sputterable materials, wherein the target includes a racetrack-shaped sputtering zone that extends longitudinally along a longitudinal axis and comprises a straightaway area sandwiched between a first turnaround area and a second turnaround area, a gas distribution system that supplies a first gas mixture to the first turnaround area and/or the second turnaround area and supplies a second gas mixture to the straightaway area, wherein the first gas mixture reduces a sputtering rate relative to the second gas mixture. In some cases, the first gas mixture includes inert gas having a first atomic weight and the second gas mixture includes inert gas having a second atomic weight, wherein the second atomic weight is heavier than the first atomic weight.

Ion implantation compositions, systems and methods are described, for implantation of dopant species. Specific selenium dopant source compositions are described, as well as the use of co-flow gases to achieve advantages in implant system characteristics such as recipe transition, beam stability, source life, beam uniformity, beam current, and cost of ownership.

An ion implantation system is described, including: an ion implanter comprising a housing defining an enclosed volume in which is positioned a gas box configured to hold one or more gas supply vessels, the gas box being in restricted gas flow communication with gas in the enclosed volume that is outside the gas box; a first ventilation assembly configured to flow ventilation gas through the housing and to exhaust the ventilation gas from the housing to an ambient environment of the ion implanter; a second ventilation assembly configured to exhaust gas from the gas box to a treatment apparatus that is adapted to at least partially remove contaminants from the gas box exhaust gas, or that is adapted to dilute the gas box exhaust gas, to produce a treated effluent gas, the second ventilation assembly comprising a variable flow control device for modulating flow rate of the gas box exhaust gas between a relatively lower gas box exhaust gas flow rate and a relatively higher gas box exhaust gas flow rate, and a motive fluid driver adapted to flow the gas box exhaust gas through the variable flow control device to the treatment apparatus; and a monitoring and control assembly configured to monitor operation of the ion implanter for occurrence of a gas hazard event, and thereupon to responsively prevent gas-dispensing operation of the one or more gas supply vessels, and to modulate the variable flow control device to the relatively higher gas box exhaust gas flow rate so that the motive fluid driver flows the gas box exhaust gas to the treatment apparatus at the relatively higher gas box exhaust gas flow rate. Preferably, in a gas hazard event, the shell exhaust discharge from the housing is also terminated, to facilitate exhausting all gas within the housing, outside as well as inside the gas box, to the treatment unit.

Compositions, methods, and apparatus are described for carrying out nitrogen ion implantation, which avoid the incidence of severe glitching when the nitrogen ion implantation is followed by another ion implantation operation susceptible to glitching, e.g., implantation of arsenic and/or phosphorus ionic species. The nitrogen ion implantation operation is advantageously conducted with a nitrogen ion implantation composition introduced to or formed in the ion source chamber of the ion implantation system, wherein the nitrogen ion implantation composition includes nitrogen (N.sub.2) dopant gas and a glitching-suppressing gas including one or more selected from the group consisting of NF.sub.3, N.sub.2F.sub.4, F.sub.2, SiF4, WF.sub.6, PF.sub.3, PF.sub.5, AsF.sub.3, AsF.sub.5, CF.sub.4 and other fluorinated hydrocarbons of C.sub.xF.sub.y (x≧1, y≧1) general formula, SF.sub.6, HF, COF.sub.2, OF.sub.2, BF.sub.3, B.sub.2F.sub.4, GeF.sub.4, XeF.sub.2, O.sub.2, N.sub.2O, NO, NO.sub.2, N.sub.2O.sub.4, and O.sub.3, and optionally hydrogen-containing gas, e.g., hydrogen-containing gas including one or more selected from the group consisting of H.sub.2, NH.sub.3, N.sub.2H.sub.4, B.sub.2H.sub.6, AsH.sub.3, PH.sub.3, SiH.sub.4, Si.sub.2H.sub.6, H.sub.2S, H.sub.2Se, CH.sub.4 and other hydrocarbons of C.sub.xH.sub.y (x≧1, y≧1) general formula and GeH.sub.4.

Some embodiments provide a magnetron sputtering apparatus including a vacuum chamber within which a controlled environment may be established, a target comprising one or more sputterable materials, wherein the target includes a racetrack-shaped sputtering zone that extends longitudinally along a longitudinal axis and comprises a straightaway area sandwiched between a first turnaround area and a second turnaround area, a gas distribution system that supplies a first gas mixture to the first turnaround area and/or the second turnaround area and supplies a second gas mixture to the straightaway area, wherein the first gas mixture reduces a sputtering rate relative to the second gas mixture. In some cases, the first gas mixture includes inert gas having a first atomic weight and the second gas mixture includes inert gas having a second atomic weight, wherein the second atomic weight is heavier than the first atomic weight.

A system, apparatus and method for increasing ion source lifetime in an ion implanter are provided. Oxidation of the ion source and ion source chamber poisoning resulting from a carbon and oxygen-containing source gas is controlled by utilizing a hydrogen co-gas, which reacts with free oxygen atoms to form hydroxide and water.

Methods, systems, and apparatus for generating hydrogen radicals for processing a workpiece, such as a semiconductor workpiece, are provided. In one example implementation, a method can include generating one or more species in a plasma chamber from an inert gas by inducing a plasma in the inert gas using a plasma source; mixing hydrogen gas with the one or more species to generate one or more hydrogen radicals; and exposing the workpiece in a processing chamber to the one or more hydrogen radicals.

An assembly for adjusting gas flow patterns and gas-plasma interactions including a toroidal plasma chamber. The toroidal plasma chamber has an injection member, an output member, a first side member and a second side member that are all connected. The first side member has a first inner cross-sectional area in at least a portion of the first side member and a second inner cross-sectional area in at least another portion of the first side member, where the first inner cross-sectional area and the second inner-cross-sectional area being different. The second side member has a third inner cross-sectional area in at least a portion of the second side member and a fourth inner cross-sectional area in at least another portion of the second side member, where the third inner cross-sectional area and the fourth inner-cross-sectional area being different.