The present invention relates to a composition for transmuting a radioactive substance into a non-radioactive substance using complex microorganisms and a method for preparing the composition.

The present invention relates to a composition for transmuting a radioactive substance into a non-radioactive substance using complex microorganisms and a method for preparing the composition.

An exothermic fusion reactor is described that uses metal-oxygen transmutation. The process comprises a negatively-charged environment; a moderator comprising at least one noble gas; a metal, including isotopes of hydrogen; and a facilitator comprising at least one element selected from the group consisting of oxygen, carbon, nitrogen, fluorine, phosphorus, sulfur, chlorine, selenium, bromine, iodine, or combinations thereof.

A method for manipulating fractal forming information, also referred to as ct states, in a dimensional form of increasing and decreasing fractal compression roughly generated by the denominator of pi (fpix), n+1, and the formula 2f(x)^(2^x) including transitional steps between those stepwise increases and decreases by altering the compression of decompression targeting fractal states of the composite dimensional features (next lower dimensional features) or the resulting dimensional features (next higher dimensional features). Steps include identifying the ct states which are to be manipulated, select a compression or decompression ct state component to change the selected ct states, adding the compression or decompression components to yield the new ct states.

Techniques for coupling fields to exotic matter at a particular location to identify, or determine the current date/time at that location, are provided. Example techniques include capturing sensor data indicating a decay rate associated with a radioactive material at the location over a period of time; analyzing the sensor data indicating the decay rate associated with the radioactive material at the location over the period of time in order to identify a peak decay rate over the period of time and a point in time, over the period of time, at which the peak decay rate occurred; and determining one or more of: a current time at the particular location, a current date at the location, or an identification of the location, based on one or more of: the peak decay rate or the point in time over the period of time at which the peak decay rate occurred.

The present invention relates to a system for a system for generating energetic particles including a device for generating an ion beam comprising a first group of atomic nuclei, and a condensed matter medium comprising a second group of atomic nuclei. The ion beam is configured to interact with the condensed matter medium so that some atomic nuclei of the first group of atomic nuclei are implanted into the condensed matter medium and undergo a first nuclear reaction thereby releasing a first energy. The ion beam is further configured to generate high-frequency phonons in the condensed matter medium. The high-frequency phonons are configured to interact with the second group of atomic nuclei and affect nuclear states of the second group of atomic nuclei by transferring the first energy of the first group of atomic nuclei to the second group of atomic nuclei and causing the second group of atomic nuclei to undergo a second nuclear reaction and emit energetic particles.

A composition of matter including a fuel comprising one or more of isotopes of hydrogen or isotopes of lithium. The general binding reactions comprise electron-catalyzed chemical, molecular, or transmutation binding reactions. The composition also includes one or more reactants having an energy-releasing binding energy with the fuel. The fuel is associated with the general binding reactions with the one or more reactants. The composition additionally includes a reservoir capable of releasing one or more of molecular fuel or mono-atomic fuel when the reservoir is heated. The reservoir comprises one or more of the fuel or precursors to the fuel, such as a chemical form of fuel in the reservoir material. The composition further includes a fuel-cracking material capable of converting a fraction of the molecular fuel into mono-atomic fuel. The composition additionally includes a reaction crystallite on or in which general binding reactions are capable of being stimulated to occur. The composition further includes a spacer. Upon the one or more reaction capsule emissions of one or more of the proximate reaction capsules, the fuel is released from the reservoir, the fuel-cracking material is brought to operating temperature, a temperature of the reaction crystallite is raised sufficient to cause crystal momentum injection, electrons are tailored by the energy-releasing binding energy and the crystal momentum injections into the reactant crystallite, and an emission of the reaction capsule energizes one or more of the proximate reaction capsules to cause a self-sustaining or chain reaction. Other embodiments are described.

A composition of matter including a fuel comprising one or more of isotopes of hydrogen or isotopes of lithium. The general binding reactions comprise electron-catalyzed chemical, molecular, or transmutation binding reactions. The composition also includes one or more reactants having an energy-releasing binding energy with the fuel. The fuel is associated with the general binding reactions with the one or more reactants. The composition additionally includes a reservoir capable of releasing one or more of molecular fuel or mono-atomic fuel when the reservoir is heated. The reservoir comprises one or more of the fuel or precursors to the fuel, such as a chemical form of fuel in the reservoir material. The composition further includes a fuel-cracking material capable of converting a fraction of the molecular fuel into mono-atomic fuel. The composition additionally includes a reaction crystallite on or in which general binding reactions are capable of being stimulated to occur. The composition further includes a spacer. Upon the one or more reaction capsule emissions of one or more of the proximate reaction capsules, the fuel is released from the reservoir, the fuel-cracking material is brought to operating temperature, a temperature of the reaction crystallite is raised sufficient to cause crystal momentum injection, electrons are tailored by the energy-releasing binding energy and the crystal momentum injections into the reactant crystallite, and an emission of the reaction capsule energizes one or more of the proximate reaction capsules to cause a self-sustaining or chain reaction. Other embodiments are described.

This invention has evolved from the discovery of how to correctly blend Einstein's Special Relativity into nuclei and atoms. That blending greatly simplifies understanding of nuclear physics. Pairs of electrically neutral relativistically warped nuclei share a huge configuration electrostatic nuclear strong force with a 1/r to the 5.3 power short range. This strong force can be either repulsive or attractive. The attractive strong force causes pairs of neutralized anti matter protons and neutralized deuterons to attract, fuse, dewarp and produce an enormous amount of relativistic mass energy. The new constituents of plasma in Tokamak and Stellarator magnetic confinement machines will consist of protons, deuterons and, for the first time ever, electrons. There is no residue from this relativistic nuclear fusion reaction. The neutrinos produced pass quickly through the walls of the reaction vessel and leave earth.

The present invention relates to a composition for transmuting a radioactive substance into a non-radioactive substance using complex microorganisms and a method for preparing the composition.