Difference between revisions of "Yuri Minovsky"

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Dr. Yuri Minovsky

Political Position(s):	Chairman of the Minovsky Physics Society
Term of Office:	March 5, 1958 - present
Predecessor:	None
Successor:	Incumbent
Birthdate:	December 2, 1923
Place of Birth:	Moscow, R.S.F.S.R., U.S.S.R.
Nationality:	Soviet (Russian)
Spouse:	None
Profession(s):	Physicist
Political Party:	Communist Party of the Soviet Union (CPSU)
Languages Spoken:	Russian, Chinese, Mongolian, Pacitalian
Degrees:	Doctorate of Science in Particle Physics Doctorate of Science in Theoretical Physics Master's of Science in Cosmology Master's of Science in Astronomy Master's of Arts in Public Administration

Yuri Minovsky, D.Sc.pp, D.Sc.tp, M.Sc.C. M.Sc.A., M.P.A., is the current Chairman of the Minovsky Physics Society and the discoverer of the M-Particle. Dr. Minovsky is one of - if not the - brightest minds on the planet. He is considered one of the foremost men in physics in the world, and has been awarded the Nobel Prize in Physics.

History

Born on December 2, 1923 to Tetter and Ivana Minovsky in Moscow, Yuri was born into a Party family. He thus was raised around politics and science the whole of his life. He aspired from his youngest memory to become a scientists. Thanks to his massive intellect and high academics, he fulfilled that dream.

Once entering secondary schooling, Yuri became active in local science exhibits and debate forums. He entered in almost every science fair in the Moscow area and won each and every one he entered. In his final year at secondary schooling, Yuri began his work on what would become known as the M-Particle. Yet, the theory revolved around the way to make a nuclear fusion reactor.

Upon entering at the University, Yuri continued his work in the liberal arts of science and cosmology. He entertained himself during the evenings by writing on the windows and in the books of the Moscow University Library. He would write out seemingly endless scientific equations and find their answer in moments. He was considered one of the most intelligent scientific minds of the time.

In 1958 - after graduating Moscow State University - Yuri founded the Minovsky Physics Society and soon there after finished his work on nuclear fusion and discovered the M-Particle (currently under scientific research and development). He began work on his next project - along with his cohorts.

Early in the years of the MPS, Dr. Minovsky helped create the first Dynamo reactor. This device has since been used almost exclusively by the Soviet Union for power. After this invention, Minovsky went off the radar until the founding of the Minovsky Physics Research Complex in the Mongolian SSR.

Technological advancements

Dr. Minovsky has been part of many research projects. The following are some of his most known projects he has either worked on, or created himself.

Minovsky reactor

Named after its inventor, this reactor was "radical" due to the fact that it was the first "clean" fusion reactor, emitting zero neutron radiation. The nuclear equation was (energy released: 18.35 MeV)
The reactant used a rare isotope of helium known as helium-3 (Ie- 2 protons and 1 neutron in the nucleus). Helium-3 is used to fuse with a deuterium atom (heavy hydrogen) to form the stable Helium-4 and a single proton. Since the proton is positively charged, it can easily be trapped within a magnetic field. The main practical problem with this reaction is that Helium-3 is extremely rare; there are little deposits on Earth, which were mainly found in Uranium mines, which are mostly depleted.

Minovsky Particle

The Minovsky Physics Society, while working on the reactor, encounter a strange electromagnetic wave effect within the Minovsky reactor that could not be explained by conventional physics. Within the next few years, they identify the cause: a new elementary particle generated by the helium-3 reaction on the inner wall of the reactor, which was named the Minovsky particle or "M" particle. The Minovsky particle has near-zero rest mass - though, like any particle, its mass increases to reflect its potential or kinetic energy - and can carry either a positive or negative electrical charge. When scattered in open space or in the air, the repulsive forces between charged Minovsky particles cause them to spontaneously align into a regular cubic lattice structure called an I-field. An I-Field lattice will slowly expand and scatter into space, however, this will take approximately 29 days before the region can retain normal electromagnetic communication again.

However, the main use of the "M" particle came into combat and communication. When the Minovsky particle is spread in large amount in the open air or in open space, the particle disrupt low-frequency electromagnetic radiation, such as microwaves and radio waves. The "M" particle also interferes with the operations of electronic circuitry and destroys unprotected ones due to their high electrical charge which act like a continuous Electromagnetic Pulse on metal objects. Because of the way Minovsky particles react with those particle types of radiations, radar systems and long-range wireless communication systems became useless, infra-red signals are defracted and decreases accuracy and visible light is fogged. This became known as the "Minovsky Effect".

The disruption of electromagnetic radiation is due to the small lattice of the I-Field creates fringes that long wave length waves cannot penetrate, and diffracts wave lengths that have similar distance with the fringes. This Diffraction and Polarization process disrupts the electromagnetic waves. Notice in real life there is a similar experimental particle that could do the same thing in few thousandth of a second, which is still not practical but proves the theory to be correct. A second utility of the I-field (and Minovsky particles in general) is the repulsion of charged plasma and chargeless Mega particles from an I-field surface, which was of use both in power generation and armament technology. If controlled, the particles can form fringes of different widths and further interfere with electromagnetic waves of shorter wave lengths, this provide the basics of the minimizing of fusion reactors installed in All Terrain Walkers since a controlled I-Field can block the infra-red waves from the high temperature from the thermonuclear reaction and reduces the need of coolant and such for the fusion reactors.

The only counter measure of the "M" particle is to install bulky and expensive shielding on all electronic equipment, but only to counteract the effect it had on electronic circuitry. While this could be done for space ships and naval ships, this ruled out the use of precision guided weapons, such as guided missiles.

Minovsky Ultracompact Fusion Reactor

Minovsky Physics Society researchers created the Minovsky ultracompact fusion reactor. Instead of the conventional magnetic field, this improved version of the Minovsky reactor used an I-field to confine and compress the reactor fuel, triggering a fusion reaction. The Minovsky particles produced as a byproduct of the helium-3 fusion reaction are thus recycled to keep that reaction going. The Minovsky particles that form the I-field lattice also help catalyze the fusion reaction. This super-efficient design is only a fifth as large as an equivalently powerful Minovsky reactor, for this reason it was adopted for use on mobile suits as the standard power plan

Mega M-Particle

Due to the repulsive forces between positive and negative Minovsky particles, large amounts of energy are required to compress an I-field lattice. If enough energy is applied, and the I-field is sufficiently compressed, the Minovsky particles ultimately fuse into massive electrically-neutral mega particles. The energy used to create the mega particles is expressed as both mass and velocity. No longer subject to the electrical forces that maintain the I-field lattice, the particles burst out of the electro-magnetic field used to compress them. The weapon will have a second I-field forming a barrel shape to prevent the mega particle from destroying the weapon that fires it. This stream of heavy fast-moving particles, unlike a conventional charged-particle beam, cannot be deflected with magnetic fields.

The Mega M-Particle is currently being researched.