Inside a furnace body with a vacuum environment or under the inert gas protection, the raw silicon material used to produce silicon carbide is melted or vaporized in a high temperature environment over 1300 C., and then the melted or vaporized raw silicon material will react with the carbonaceous gas or liquid to form silicon carbide. The present invention uses the carbonaceous gas with no metallic impurities, to replace petroleum coke, resin, asphalt, graphite, carbon fiber, coal, charcoal and some other carbon sources used in current production processes. When the carburizing reaction is in progress, the raw silicon material is melted or vaporized and the reaction takes place in the air. No container is required, so impurity contamination is lessened, and the produced silicon carbide has a fairly high purity.

A high temperature heat integration method of making carbon black. A method of making carbon black is described, including reacting a carbon black forming feedstock with hydrogen gas in a plasma reactor to produce effluent gas containing carbon black and unused hydrogen, cooling the effluent gas for further processing, and recycling the unused hydrogen back into the carbon black forming process, where the unused hydrogen gas is pre-heated in a heat exchanger to a temperature up to the reaction temperature in the reactor before being recycled into the carbon black forming process. The heat exchanger for use in such process is also described.

A system for creating a nitrate combined with a liquid. A corona discharge cell to generate an electrical field. The corona discharge cell further comprising a conduit to pass air through the electrical field to produce nitric oxide NO, wherein the air comprises a mixture of at least nitrogen N.sub.2 and oxygen O.sub.2, the conduit for combining the nitric oxide NO with the oxygen O.sub.2 to form nitrogen dioxide NO.sub.2. The corona discharge cell further comprising an injector for combining the nitrogen dioxide NO.sub.2 with the liquid to generate nitric acid HNO.sub.3 which combines with the liquid to generate the nitrate comprised of nitrate radical NO.sub.3 mixed with the liquid.

A nitric oxide generator generates nitric oxide from a mixture of nitrogen and oxygen such as air treated by a pulsating electrical discharge. The desired concentration of nitric oxide is obtained by controlling at least one of a frequency of the pulsating electrical discharge and duration of each electrical discharge pulse.

The present disclosure relates to a plasma reactor for plasma-based gas conversion comprising a pin electrode extending along a longitudinal axis from a first end to a second end, an opposing electrode opposing a discharge tip of the 10 pin electrode, a plasma chamber for confining a glow discharge plasma, and an electrically-insulating body that comprises an inner bore extending along the longitudinal axis from a bore entrance to a bore exit. The second end of the pin electrode comprises a discharge tip. The pin electrode penetrates the inner bore from the bore entrance and extends at least partly through the inner bore and a15 radial wall of a portion of the inner bore located between the second end of the pin electrode and the opposing electrode, is radially delimiting the plasma chamber. The plasma reactor is further configured for varying an electrode separation distance between the discharge tip of the pin electrode and the opposing electrode.

The invention relates to a reactor for dielectric barrier discharge plasma catalysis, comprising a reactor housing (B) able to receive a plurality of DBD cells (C1, C2, C3 . . . ) removably mounted inside this housing.

Systems and methods are provided for generating a nitric oxide (NO) gas. A plasma generating device is configured to produce a plasma to ionize a flow of a reactant gas into a product gas that comprises NO, NO.sub.2, oxygen, and nitrogen gases. A controller is configured to regulate an amount of NO in the product gas using parameters as input to the controller. A gas separation device comprising a housing including product gas inlets and sweep fluid inlets to receive a flow of the product gas and a flow of the sweep fluid such that the flows of product gas and sweep fluid are opposed flows. A membrane is positioned inside the housing and permits flow of a subset of gases of the product gas therethrough so the product gas exiting the housing includes NO.

A photocatalytic device includes a substrate and an array of conductive projections supported by the substrate and extending outward from the substrate. Each conductive projection of the array of conductive projections has a semiconductor composition configured for charge carrier generation in response to solar radiation. Each conductive projection of the array of conductive projections is decorated with a co-catalyst arrangement. The co-catalyst arrangement includes gold and an oxide material.

The invention relates to a device (4) for carrying out a chemical rection in a plasma (223), wherein the device (4) comprises a source for generating electromagnetic waves (211), at least one first reactor (200), at least one connecting piece (230) and a second reactor (240). The invention also relates to a method for carrying out the chemical reaction using the device (4).

The present invention relates generally to an ammonia capture system or method comprising plasma NOx and, more particularly to such system and method for ammonia capture comprising a two-tank NOx absorption system. Furthermore the present invention concerns a system to produce ammonium nitrate in solution or as a solid from atmospheric ammonium.