Detecting new types of nuclear fusion reactions

Scientists have discovered a new type of nuclear fusion that ensures high energy efficiency and utilizes seawater without costly fuel.

Scientists at Sandia National Laboratory (USA) have conducted a series of simulation experiments on computers and argue that nuclear fusion with very high amplification efficiency (ie higher output energy much more than the input energy) can be achieved by a cylindrical container overheated in a strong magnetic field.

Calculations show that this new generator produces much more energy than the energy needed to initiate the reaction. The new method is 50 times more effective than using dangerous jet rays.

One of the inventors of this invention, Steve Sluts, said: 'Probably no one believes the performance of the' magnetized inertial fusion '(abbreviated MIF), but mathematical calculations. "We need to do that now. I myself don't see any obstacles to successful implementation of the experiment."

Equipment synthesized from fire inertia on computer models.

The MagLIF device model will be tested and the first results of the promising results of the machine will be announced at the end of 2013.

New high-performance synthesis technology can produce clean, eco-friendly energy in much greater amounts than energy used to sustain reactions. When modeling, the energy output exceeds the input energy by up to 100 times - when the input current is 60 million ampere. If the intensity of the input current reaches 70 million ampere, the output current increases to 1,000 times.

Method of 'inertia synthesis' MIF is based on compressing a small amount of fuel in a few nanoseconds. In the future, it will ensure reliable power supply by utilizing both cheap and even inexpensive materials on our planet as seawater.

Currently, in the laboratory, scientists have not succeeded in improving the output energy compared to the input, because only the intensity of the input current of 26 million amps has been generated. Although Sandia laboratory equipment is heated by nuclear fuel (deuteri, triti) when compressed (in a moment of MIF reaction) and uses magnetic fields to reduce heat loss.

The magnetic field acts like a 'curtain' to prevent charged particles from escaping from the reaction area and reducing its energy. The process is based on one of the relatively low intensity lasers to heat the mixture of deuterium and tritium gas. That heating is only enough to provide heat to the reaction.

The testing of equipment to re-examine computer modeling data has been initiated and the results of laboratory research on new types of nuclear fusion are eagerly awaited by the end of the year. two thousand and thirteen.