RU2005104090A - METHOD OF CONCENTRATION AND ACCUMULATION OF ELECTROMAGNETIC ENERGY IN THE PLASMA OF THE MEDIA - Google Patents

Claims (2)

1. The method of concentration and accumulation of electromagnetic energy in a plasma medium, including the formation of an optical path in which long waves (solitons) arise and move and the formation of strong magnetic fields in crossed laser beams, characterized in that for the formation in the optical path of a chain of long standing Langmuir or ion-sound waves in a magnetized plasma of the optical path, with the parameters of the soliton conjugated with the parameters of the optical path and the optical mixer of ionized gas into the gas discharge the second chamber of an electromagnetic oscillation generator with a tunable frequency of stimulated radiation, which produces a laser or hypersonic beam when excited in an optical mixer of a gas-discharge chamber of ion-sound or Langmuir turbulence (depending on the embodiment), which determines the accompanying radiation with the main in the form of spiral (helicon) waves, in the interaction of the main and accompanying radiation with the excitation of the medium near the beam at temperature and electron-cyclotron resonance due to microwave radiation, with the suppression of distortions determined by the difference in density, temperature and charge inhomogeneity of the medium in which the optical path is formed when exposed to longitudinal mechanical vibrations in the low and medium frequencies, determining the adaptive generator in design optical resonances when combining an electromagnetic oscillation generator with a tunable frequency of stimulated radiation mounted in the aperture of a paraboloid mirror rotation (in shape) with a hole in the center, illuminated by a multi-antenna microwave radiation generator, with a microwave radiation generator, and the perimeter mirror is rigidly fixed with mechanical vibrators, which determine the mechanical vibrations of the mirror as a plane and the longitudinal mechanical vibrations propagating from it in the low and medium frequencies, determining this device is capable of both generating radiation and interacting with this radiation with the conversion of energy into electric current, and with the coaxial placement of two genes of radiators in space toward each other with their radiating sides, determines the formation of the optical path in the plasma: magnetic heterogeneity, defining the magnetized plasma as a dispersing medium, expressed in the formation of the blanket shell of the optical path (such as a spatial “shear”), consisting of placement along the length of the optical path transverse axes of magnetic fields around which the lines of force are twisted, arising taking into account the "freezing" of the lines of force and the noncollinearity of the electron temperature gradients s and density; conditions of the nonlinearity of the medium defined in the formation of a longitudinal drift of self-generated polarization planes (elliptical) with a Bragg angle of inclination with respect to the longitudinal axis of the optical path and rotating with Larmor precession in the volume of the optical path as a cylinder with an internal radius equal to the limit of the Larmor radius that increased to parameters of the optical tract, defining under conditions of birefringence as a medium - optically negative, as well as the formation of a current coil with negative impedance formed during the self-intersection of two rotating polarization planes (from countercurrent flows) in the form of a caustic with the distance between the current turns formed along the longitudinal axis of the optical path, determined by the in-phase amplitude thermodynamic self-consistency in the plasma of the optical path at the thermopower and gradients of electron temperature and density in the collinear interaction of their vectors with current turns - as a closed or zero vector with acceleration of a particle beam in the optical path for parametric self-matching of oncoming flows of traveling solitons from generators located at a considerable distance at the ends of the optical path and the formation of a longitudinal negative inductance in the plasma, as well as the formation of energy equilibrium in the optical path when magnetic fields interact under freezing conditions with muon formation in the plasma under the conditions of removing "degeneracy", in the event of the occurrence of axial x-ray radiation in the plasma, and chemical energy during oxidation-reduction overall reactions. 2. The method of concentration and accumulation of electromagnetic energy in a plasma medium according to claim 1, characterized in that when a soliton of a standing wave of the optical path penetrates into the optical mixer of the gas-discharge chamber of the receiving device, it determines the resonance with increasing amplitude of the gradient drift, determining the development of instability with the drift of charged particles and clusters of positive ions in the area of the heat-reflecting plate with a thermal helix and negative charges in the area of the control electrode, determining the potential difference at the terminal x, mounted on the reflecting plates of the electromagnetic radiation generator with a tunable frequency of stimulated radiation, to which current consumers are pre-connected, while the gradient drift is determined by rotation of the polarization planes i.e. not of electrical origin, but rather of nuclear processes during the removal of “degeneracy,” as determined by the gradient drift condition, but the formation of instability and determined by the muon formation as an inert mass (by analogy as the formation of waves behind a moving ship).