Energy 1.0 lmt crossfire fusion reactor 10x7 ft

How the Crossfire Fusion reactor uses helium 3 Fact: 1. The ingredients for fusion are deuterium, tritium, and isotopes of Helium 2. Electrons are shared between atoms 3. Deutrium + He3 -> proton(14.7 MeV) + He4 (3.7 MeV) + 18.4 MeV (Mass converted to energy) 4. A Deuterium + He3 reactor is optimal at 100 KeV. Crossfire fusion reactor: Electrons go to the ground and positive ions are accelerated in an electrostatic way against a negative potential. Meaning little power is required to reach a great kinetic energy (600 KeV for Boron hydrid). The Crossfire reactor uses a superconductor magnet 4.5 tesla to focus confinement; a superconducting magnet for exhausting plasma, a dielectric mirror for reflecting electromagnetic waves back to plasma. Plasma positive ion will attract electrons from neutralizers. The system will receive energy from plasma allowing the flux of electrons from ground to positive potential. The system will transfer energy to plasma pulling electrons from ground to negative potential. (Reference Link) 5. 1 million metric tonnes of He3, reacted with deuterium, would generate about 20,000 terrawatt-years of thermal energy (Reference Link) 6. About 25 tonnes of He3 would power the United States for 1 year at our current rate of energy consumption 7. Mark Suppes builds a small fusion reactor that uses deuterium gas as a fuel. The reactor puts off 30,000 volts with negligible amounts of radiation. The reactor is zero sum and not a golden reactor, but it does demonstrate potential. (Reference Link) 8. Helium 3 deteriorates into tritium. He3 represents 0.0002 percentage of all Helium. World demand for He3 is 76,000 liters per year, whereas, US demand is 8,000 liters. (Reference Link) 9. Could you mine moon rocks with robots to extract Helium 3 for fusion reactors on earth? (Reference Link)