A plasma generator includes a cylindrical containment housing, an anode in a confinement space within the containment housing and a cathode within the anode. The cylindrical containment housing includes an open end and a closed end. A base forms the closed end. That base includes a first gas inlet and a first gas outlet.

Laser amplification utilizing plasma confinement of a gas laser gain media is described. The gas laser gain media is compressed into plasma utilizing a self-reinforcing magnetic field referred to a plasma pinch (e.g., a flow stabilized z-pinch). In the plasma pinch, the gas laser gain media is compressed to a high density, which improves the gain of the media. An optical resonator partially surrounds the plasma pinch and utilizes the laser gain media compressed within the plasma pinch to generate an output of coherent light.

An apparatus for a material synthesis technology by microwave plasma torch with atmospheric pressure and high temperature. The apparatus includes a plasma torch system and a material growth system. In the plasma torch system, the cutting-edge breakdown happens through inputting the high-power microwave. Then the stable plasma torch with atmosphere pressure and high temperature is achieved in precursor at the open-end of the cylindrical metal tube. The precursors are decomposed by the plasma torch with high temperature and the active particles for material growth are achieved. In the material growth system, the motion and ingredients proportion of negative and positive icons or particles in the active particle beam are controlled by the adjustable static electric field in the space between the plasma torch and material growth space. The material-controlled growth is implemented by the heating system and the adjustable static electrical field.

An apparatus for a material synthesis technology by microwave plasma torch with atmospheric pressure and high temperature. The apparatus includes a plasma torch system and a material growth system. In the plasma torch system, the cutting-edge breakdown happens through inputting the high-power microwave. Then the stable plasma torch with atmosphere pressure and high temperature is achieved in precursor at the open-end of the cylindrical metal tube. The precursors are decomposed by the plasma torch with high temperature and the active particles for material growth are achieved. In the material growth system, the motion and ingredients proportion of negative and positive icons or particles in the active particle beam are controlled by the adjustable static electric field in the space between the plasma torch and material growth space. The material-controlled growth is implemented by the heating system and the adjustable static electrical field.

Laser amplification utilizing plasma confinement of a gas laser gain media is described. The gas laser gain media is compressed into plasma utilizing a self-reinforcing magnetic field referred to a plasma pinch (e.g., a flow stabilized z-pinch). In the plasma pinch, the gas laser gain media is compressed to a high density, which improves the gain of the media. An optical resonator partially surrounds the plasma pinch and utilizes the laser gain media compressed within the plasma pinch to generate an output of coherent light.

A system and method for containing plasma and forming a Field Reversed Configuration (FRC) magnetic topology are described in which plasma ions are contained magnetically in stable, non-adiabatic orbits in the FRC. Further, the electrons are contained electrostatically in a deep energy well, created by tuning an externally applied magnetic field. The simultaneous electrostatic confinement of electrons and magnetic confinement of ions avoids anomalous transport and facilitates classical containment of both electrons and ions. In this configuration, ions and electrons may have adequate density and temperature so that upon collisions ions are fused together by nuclear force, thus releasing fusion energy. Moreover, the fusion fuel plasmas that can be used with the present confinement system and method are not limited to neutronic fuels only, but also advantageously include advanced fuels.

A system and method for containing plasma and forming a Field Reversed Configuration (FRC) magnetic topology are described in which plasma ions are contained magnetically in stable, non-adiabatic orbits in the FRC. Further, the electrons are contained electrostatically in a deep energy well, created by tuning an externally applied magnetic field. The simultaneous electrostatic confinement of electrons and magnetic confinement of ions avoids anomalous transport and facilitates classical containment of both electrons and ions. In this configuration, ions and electrons may have adequate density and temperature so that upon collisions ions are fused together by nuclear force, thus releasing fusion energy. Moreover, the fusion fuel plasmas that can be used with the present confinement system and method are not limited to neutronic fuels only, but also advantageously include advanced fuels.

Enhanced Coulomb repulsion (electron) screening around light element nuclei is achieved by way of utilizing target structures (e.g., nanoparticles) that undergo plasmon oscillation when subjected to electromagnetic (EM) radiation, whereby transient high density electron clouds are produced in localized regions of the target structures during each plasmon oscillation cycle. Each target structure includes an integral body composed of an electrically conductive material that contains light element atoms (e.g., metal hydrides, metal deuterides or metal tritides). The integral body is also configured (i.e., shaped/sized) to undergo plasmon oscillations in response to the applied EM radiation such that the transient high density electron clouds are formed during each plasmon oscillation cycle, whereby brief but significantly elevated charge density variations are generated around light element (e.g., deuterium) atoms located in the localized regions, thereby enhancing Coulomb repulsion screening to enhance nuclear fusion reaction rates. Various target structure compositions and configurations are disclosed.

Enhanced Coulomb repulsion (electron) screening around light element nuclei is achieved by way of utilizing target structures (e.g., nanoparticles) that undergo plasmon oscillation when subjected to electromagnetic (EM) radiation, whereby transient high density electron clouds are produced in localized regions of the target structures during each plasmon oscillation cycle. Each target structure includes an integral body composed of an electrically conductive material that contains light element atoms (e.g., metal hydrides, metal deuterides or metal tritides). The integral body is also configured (i.e., shaped/sized) to undergo plasmon oscillations in response to the applied EM radiation such that the transient high density electron clouds are formed during each plasmon oscillation cycle, whereby brief but significantly elevated charge density variations are generated around light element (e.g., deuterium) atoms located in the localized regions, thereby enhancing Coulomb repulsion screening to enhance nuclear fusion reaction rates. Various target structure compositions and configurations are disclosed.

A method of containing plasma and forming a Field Reversed Configuration (FRC) magnetic topology. A magnetic guide field is created within a cylindrical chamber. The guide field has field lines axially extending within the chamber parallel to the longitudinal axis. A plasma of charged electron and ion particles is injected into the chamber. The plasma is caused to rotate, which forms a magnetic poloidal self-field surrounding the rotating plasma due to the current carried by the rotating plasma. The rotational energy of the plasma is increased to increase the magnitude of the self-field to a level that overcomes the magnetic guide field axially extending within the chamber, which causes the formation of a magnetic field within the chamber with FRC topology.