Systems and methods for plasma based synthesis of graphitic materials. The system includes a plasma forming zone configured to generate a plasma from radio-frequency radiation, an interface element configured to transmit the plasma from the plasma forming zone to a reaction zone, and the reaction zone configured to receive the plasma. The reaction zone is further configured to receive feedstock material comprising a carbon containing species, and convert the feedstock material to a product comprising the graphitic materials in presence of the plasma.

Aspects of the present disclosure involve a plasma system for practicing various methods of synthesizing solid-state electrolyte materials and precursors for solid-state electrolyte materials.

The present invention relates to the corona discharge-induced cracking of hydrogen-containing gas into molecular hydrogen and at least one by-product, or the production of molecular hydrogen and at least one by-product, or the production of downstream products from the molecular hydrogen and/or the at least one by-product. To this end, hydrogen-containing gas is fed via a gas supply line into a gas-tight reaction chamber with exactly one plasma electrode. The gas-tight reaction chamber is enclosed by a wall that is designed to electrically insulate the plasma electrode from an outside of the wall. The plasma electrode is connected to a high-frequency generator that provides high-frequency alternating voltage and generates corona discharges in the reaction chamber by means of the high-frequency alternating voltage. This results in the cracking of hydrogen-containing gas into molecular hydrogen and at least one by-product. The molecular hydrogen is discharged from the reaction chamber via a gas discharge line. The hydrogen-containing gas can contain, for example, methane, biogas, natural gas, hydrogen sulfide, or cyclohexane, heptane, toluene, gasoline, JP-8, or diesel that have been converted into the gaseous aggregate state.

A method and system for reforming CO.sub.2 rich natural gases is disclosed which comprises: a cold plasma unit configured to convert CO.sub.2 rich natural gases into a plasma state; and a gas reforming reactor configured to reform said CO.sub.2 rich gas mixture at said plasma state into a syngas. The catalytic reforming reactor is separate and different from the DBD cold plasma unit. Means for latent heat of condensation, endothermic/exothermic reactions, and convection currents is used to achieve energy efficiency.

A system for treating a substrate comprising a treatment module and a substrate plane. The substrate extending along a substrate plane to treat the substrate and wherein a fluid is deliverable via the module to a local region between the module and the substrate plane to treat the substrate with a predetermined treatment.

Embodiments of the subject invention relate to a small modular self-contained surface plasma device for decontamination of air and surfaces within enclosed volumes. Embodiments of the subject invention relate to a method and apparatus using the technical process of dielectric barrier discharge (DBD) surface plasma generation from ambient atmosphere for decontamination of air and surfaces within enclosed volumes. The primary application mode is for preservation of perishable commodities within industrial shipping containers through reduction of surface spoilage organisms and destruction of evolved gaseous ethylene that causes premature ripening. Additional implementations include deployment for oxidation of surfaces and/or container atmospheres in applications to diminish or eradicate pesticides, toxins, chemical residues, and other natural or introduced contaminants. Other embodiments envisioned include incorporation of device capabilities and or ancillary modules for feedback input (e.g. ozone sensor(s) to maintain steady state levels, self-tuning circuitry to adjust operating frequency), communication (e.g. among modules, RFID data loggers, Wi-Fi output), and programing (e.g. user input of container volume, transit time, ozone level, etc.).

Bacteriophage is covalently attached to a substrate by (a) combining (i) substrate with (ii) bacteriophage, wherein prior to or during the combining (i) or (ii) or both (i) and (ii) are activated, and wherein (b) during the combining the bacteriophage is contained within a liquid droplet of average diameter 150 microns or less.

An improved device and process for the production of oxides of nitrogen (NOx) having a novel plasma reactor assembly (105) with a gas and water injector (104) that mixes gas (10) and water (103) to produce gas and micro-fine water droplets (106) and injects same into a plasm reactor vessel (125) between electric diodes (128, 129) to yield a nitrous-rich plasma product (107) which is useful in a variety of commercial, agriculture, medical and industrial arenas.

The present invention relates to a method for treating a sample using glow-discharge plasma, in an apparatus comprising a treatment vessel, an electrode, a counter-electrode, and a power supply comprising one or more transformers and having a first transformer setting and a second transformer setting, the method comprising: (i) a loading step, involving loading the sample into the treatment vessel; (ii) a first treatment step involving treating the sample in a glow-discharge plasma formed within the treatment vessel by applying an electric field between the electrode and counter-electrode at the first transformer setting; (iii) a second treatment step involving treating the sample in a glow-discharge plasma formed within the treatment vessel by applying an electric field between the electrode and counter-electrode at the second transformer setting; and (iv) a removal step, involving removing treated sample from the treatment vessel. The method can be used to functionalize a sample. The present invention also relates to an apparatus for use in such a method.

A method for exfoliating and/or functionalising lamellar objects is discussed. The steps include immersing at least one portion of a first electrode in a liquid containing the lamellar objects to be exfoliated and/or functionalised, placing a second electrode outside the liquid, at least one portion of the second electrode being opposite a surface of the liquid, generating a plasma between at least one portion of the second electrode facing the surface of the liquid and the surface of the liquid by applying a pulse voltage difference between the first and the second electrode.