Microwave chemical processing system having a microwave plasma reactor, and a multi-stage gas-solid separation system are disclosed. The microwave energy source has a waveguide, a reaction zone, and an inlet configured to receive the input material, and the input material is converted into separated components. The separated components include hydrogen gas and carbon particles. The multi-stage gas-solid separation system has a first cyclone separator to filter the carbon particles from the separated components, and a back-pulse filter system coupled to the output of the first cycle separator to filter the carbon particles from the output from the first cyclone separator.

Microwave chemical processing system having a microwave plasma reactor, and a multi-stage gas-solid separation system are disclosed. The microwave energy source has a waveguide, a reaction zone, and an inlet configured to receive the input material, and the input material is converted into separated components. The separated components include hydrogen gas and carbon particles. The multi-stage gas-solid separation system has a first cyclone separator to filter the carbon particles from the separated components, and a back-pulse filter system coupled to the output of the first cycle separator to filter the carbon particles from the output from the first cyclone separator.

A microwave mode coupling device for transferring electromagnetic (EM) energy from a first structure to a second structure while providing a pressure barrier between the first structure and the second structure, the coupling device comprising first and second transmission line sections separated by an intermediate waveguide section.

A Traveling Wave Reactor (TWR) includes an inner microwave-transparent tube including an inlet and an outlet; an outer resonant tube surrounding a section of the microwave-transparent tube; a microwave source operable to provide microwave radiation to the resonant tube, wherein the microwave radiation creates a traveling microwave field in the resonant tube; and a tube rotator operable to rotate the microwave-transparent tube. A method for H.sub.2S treatment includes introducing a gas comprising H.sub.2S into a Traveling Wave Reactor (TWR), wherein the TWR includes a microwave source and a microwave-transparent tube including a catalyst bed; contacting the gas with the catalyst bed; and irradiating the catalyst bed with microwaves emitted by the microwave source, thereby activating a conversion of H.sub.2S.

A system includes a first chamber, a second chamber, an ultraviolet light source and a microwave source. The first chamber includes an inlet. The second chamber is adjacent the first chamber and includes an outlet and a waveguide. The ultraviolet light source resides within the waveguide of the second chamber. Related apparatus, systems, techniques and articles are also described.

A microwave reactor constructed to produce a homogeneous heat distribution across the body of the microwave reactor subsequent exposure to microwave irradiation. The microwave reactor includes a body having an exterior wall transparent to microwave irradiation. A microwave sensitized element layer is adjacent the exterior wall and is comprised of a carbide mixture wherein the carbide mixture includes a carbide mixed with either a metal oxide, a ferrite or a nitride. The carbide mixture is in granular form wherein the carbide has a larger particle size than the other component. The microwave sensitized element layer further includes a metal layer that extends the length thereof. The metal layer is positioned in various arrangements within or adjacent to the carbide mixture. The body further includes an inner layer adjacent to the microwave sensitized layer opposite the exterior wall. The inner layer is transparent to microwave irradiation.

A system for producing fixed nitrogen products includes a header coupled to one or more plasma torch reactors. The plasma torch reactors receive input gases and generate (e.g., using microwave energy) a plasma and resulting reactive nitrogen species. The reactive nitrogen species oxidize within the header, resulting in a product stream. In certain implementations, the product stream is transported to an absorption unit for conversion into the fixed nitrogen products. Certain implementations include cooling, supplemental fluid, and other systems to vary and enhance production of fixed nitrogen products and operation of the system.

A microwave reduction furnace including a reaction furnace provided with a refractory chamber of silica or silicon carbide for storing a material therein, a supply section for supplying the material into the refractory chamber, the material being a mixture of a silica powder and a graphite powder or a mixture of a silica powder, a silicon carbide powder and a graphite powder, a discharge section for discharging molten silicon, obtained through reduction, out of the chamber, and a microwave oscillator for outputting microwave toward the refractory chamber in the reaction furnace with a degree of directionality by virtue of a helical antenna or a waveguide.

A fuel activation and energy release apparatus is provided for increasing energy output of a fluid substance. The apparatus comprises a fluidly sealable reactor chamber, adapted to withstand a predetermined fluid pressure and temperature; a fluid injection port, adapted to provide a one-way fluid communication from an external fluid reservoir to said reactor chamber; a fluid ejection port, adapted to provide a one-way fluid communication from said reactor chamber to an external region, so as to controllably release said fluid substance from said reactor chamber and at least one first electromagnetic radiation (EMR) waveguide. The first EMR waveguide having a first waveguide input port and a first waveguide output port, operably coupled within said reactor chamber and adapted to couple electromagnetic radiation of a predetermined first wavelength to a fluid substance injected into said reactor chamber.

A non-thermal plasma is generated to selectively convert a precursor to a product. More specifically, plasma forming material and a precursor material are provided to a reaction zone of a vessel. The reaction zone is exposed to microwave radiation, including exposing the plasma forming material and the precursor material to the microwave radiation. The exposure of the plasma forming material to the microwave radiation selectively converts the plasma forming material to a non-thermal plasma including formation of one or more streamers. The precursor material is mixed with the plasma forming material and the precursor material is exposed to the non-thermal plasma including exposing the precursor material to the one or more streamers. The exposure of the precursor material to the streamers and the microwave radiation selectively converts the precursor material to a product.