In one aspect, a method is described. The method may include exposing a printing surface to a first plasma in order to increase a hydrophilicity of the printing surface. The method may further include, after increasing the hydrophilicity of the printing surface, depositing a printing material on the printing surface. Additionally, the method may include, after depositing the printing material on the printing surface, exposing the printing surface to a second plasma in order to increase a hydrophobicity of the printing surface.

A microwave plasma treatment device includes a resonator including a container; a single microwave oscillation source that outputs a reference microwave; a waveguide that connects the microwave oscillation source and the resonator to each other; and a phase control mechanism that generates a modified microwave having a phase different from a phase of the reference microwave by controlling the phase of the reference microwave. The resonator includes one or more first-type introducing portions for introducing the reference microwave into the resonator and one or more second-type introducing portions for introducing the modified microwave into the resonator, and the microwave plasma treatment device is configured such that at least one of a position, a size, and a shape of a plasma ball generated in the container is changed by superimposing the modified microwave on the reference microwave in the resonator.

A localized heating device includes a plasma deforming portion and a heating portion. The plasma deforming portion includes an inlet end having a circular hole, an outlet end having an elongated hole with a first length and a first width, and a channel smoothly connected with the circular hole and the elongated hole. The heating portion, disposed at the outlet end, includes two control covers spaced by a slot. The elongated hole and the slot being oppositely disposed with respect to the plasma deforming portion. A plasma flow provided by a plasma producing source being to enter the channel via the circular hole, then to flow through the elongated hole, and finally to reach the slot.

A power generator is described that provides at least one of electrical and thermal power comprising (i) at least one reaction cell for reactions involving atomic hydrogen products identifiable by unique analytical and spectroscopic signatures, (ii) a molten metal injection system comprising at least one pump such as an electromagnetic pump that provides a molten metal stream to the reaction cell and at least one reservoir that receives the molten metal stream, and (iii) an ignition system comprising an electrical power source that provides low-voltage, high-current electrical energy to the at least one steam of molten metal to ignite a plasma to initiate rapid kinetics of the reaction and an energy gain. In some embodiments, the power generator may comprise: (v) a source of H.sub.2 and O.sub.2 supplied to the plasma, (vi) a molten metal recovery system, and (vii) a power converter capable of (a) converting the high-power light output from a blackbody radiator of the cell into electricity using concentrator thermophotovoltaic cells with light recycling or (b) converting the energetic plasma into electricity using a magnetohydrodynamic converter.

An inductively coupled plasma (ICP) torch includes: an injector defining an injector flow passage to receive a flow of a sample fluid; a plurality of tubes disposed about the injector and configured to receive and direct a flow of one or more torch gases; an induction device disposed about the plurality of tubes, the induction device configured to receive a radio-frequency electric current to inductively energize at least one of the one or more torch gases to produce a plasma proximate a distal end of the ICP torch; and a plasma steering system including a plurality of nozzles adjacent a distal end of the injector flow passage and configured to receive and direct a flow of steering fluid to impinge and redirect the flow of sample fluid and to thereby redirect an ionized sample resulting from the interaction of the sample fluid with the plasma.

A light emitting sealed body includes a housing which stores a discharge gas in an internal space and is provided with a first window portion to which first light is incident and a second window portion from which second light is emitted. The housing includes at least one flow path which is partitioned from the internal space and extends toward at least one of the first window portion and the second window portion.

A method of sterilizing an object with atomic nitrogen from a nitrogen plasma comprises the steps of positioning the object in a sterilization chamber, and conditioning the object present in the chamber. The step of conditioning includes a first stage of injecting atomic nitrogen into the chamber, during which a first concentration of atomic nitrogen in the chamber is imposed, a suction stage performed after the first injection stage, during which the chamber is evacuated, and a second stage of injecting atomic nitrogen into the chamber that is performed after the suction stage, during which a second concentration of atomic nitrogen is imposed in the chamber. The method further comprises a sterilization step of sterilizing the object, performed after the conditioning, and includes injecting atomic nitrogen into the chamber, during which step a concentration of atomic nitrogen in the chamber is imposed that is greater than the first and second concentrations.

A method of sterilizing an object with atomic nitrogen from a nitrogen plasma includes the steps of placing the object in a sterilization chamber and a sterilization half-cycle for sterilizing the object present in the chamber. The sterilization half-cycle comprises an alternation between stages of injecting atomic nitrogen into the chamber and of intermediate stages, each intermediate stage including at least one suction stage during which the chamber is evacuated.

[Object] To predict the damage distribution of a workpiece caused by ions and light from plasma more accurately within a practical computation time. [Solution] Provided is a damage prediction method including: using an operation apparatus to calculate, from fluxes of ions and light generated by plasma, fluxes of ions and light propagated through a pattern of a workpiece including a processing object, on the basis of the pattern; calculating, from the fluxes of ions and light propagated through the pattern, fluxes of ions and light arriving at a surface of the processing object, by ray tracing; and calculating, from the fluxes of ions and light arriving at the surface of the processing object, a damage distribution of the processing object.

A surface treatment system includes a holder configured to secure an object within the holder and a surface treatment device that is configured to treat a surface of the object within the holder with two types of surface treatments. The device is capable of producing a plasma or a flame at its nozzle for surface treatment. By controlling the materials supplied to the device and the way in which is operated, either a flame or plasma is produced. Thus, the surface treatment system is capable of treating a wide range of materials for printing by a direct-to-object printer.