Minovsky Physics

The Minovsky Physics Society was formed in U.C.0045 at the space colony Side 3. Their research was devoted to the development of a nuclear fusion reactor. By the year U.C.0047, development of the Minovsky-Ionesco reactor began. This reactor, although designed by Dr. T.Y. Minovsky in his earlier days when he was serving the Earth Federation, was still a piece of black box technology and rendered him a heretic in the classical physics community (where classical in the Universal Century includes the modern physics of today). This is the main reason for his termination of service in the Earth Federation and taking residence in Side 3 prior to the One Year War. However, seeing the horror of the Chrysylophax family's militaristic regime, Minovsky defected back and offered his expertise to the Federation. However, his inventions were applied very differently by the Earth Federation.

The Minovsky-Ionesco reactor was named after its fictional inventor. This reactor was "radical" due to the fact that it was the first "clean" nuclear reactor, emitting zero neutron radiation.

The reactant used a rare isotope of helium known as helium-3 (i.e., 2 protons and 1 neutron in the nucleus). A helium-3 atom is fused 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 few deposits on Earth, mainly found in uranium mines, and these are mostly depleted. The UC3K world's fusion reactors rely on a constant supply of helium-3 imported from the outer solar system planet Jupiter, thus necessitating the beginning of the Jupiter Energy Fleet. The JEF would travel from Earth to Jupiter, which has a high level of helium-3 in its atmosphere, and then come back to Earth with the gas fuel. It should be noted that in real physics, helium-3-deuterium fusion produces neutrons due to inevitable deuterium-deuterium reactions. Also, significant quantities of helium-3 were recently discovered on the moon, although there is certainly much more on Jupiter.

The Minovsky Particle

The Minovsky Physics Society, while working on the reactor, encountered a strange electromagnetic wave effect in U.C.0065 within the Minovsky-Ionesco reactor that could not be explained by conventional physics. Within the next few years, they identified 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, after dense interference it will take approximately 29 days before the region can support normal electromagnetic communication again.

The main use of the Minovsky particle was in combat and communication. When the Minovsky particle is spread in large numbers in the open air or in open space, the particles disrupt low-frequency electromagnetic radiation, such as microwaves and radio waves. The Minovsky particle also interferes with the operations of electronic circuitry and destroys unprotected circuits due to the particles' high electrical charge which act like a continuous electromagnetic pulse on metal objects. Because of the way Minovsky particles react with other types of radiation, radar systems and long-range wireless communication systems become useless, infra-red signals are diffracted and their accuracy decreases, 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 creating fringes that long wavelengths cannot penetrate, and that diffract wavelengths 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 use of the I-field (and Minovsky particles in general) was 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 wavelengths. This provides the basis for the miniaturizing of fusion reactors installed in battle mechs since a controlled I-field can block the infra-red waves. This reduces the heat from the thermonuclear reaction and reduces the need for coolant and shielding for the fusion reactors. Without such a field, a pilot would be boiled alive in a few nanoseconds and the suit would burst into superheated gasses, thus explaining many of the series' casualties when the reactor of a battle mech is pierced with a beam weapon powerful enough to disperse this I-field.

The only counter measure to the "M" particle in the series was 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. Due to this, the military use of Minovsky particles ushered in a new era of close-range combat. This is the primary reason for the birth of the NEO close-combat weapon: the battle mech.

Minovsky Ultracompact Fusion Reactor

In UC 0071, NEO researchers created the Minovsky ultracompact fusion reactor. Instead of the conventional magnetic field, this improved version of the Minovsky-Ionesco 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 were recycled to keep that reaction going. The Minovsky particles that form the I-field lattice also helped catalyze the fusion reaction, in a process similar to the muon-catalyzed fusion investigated by real-world scientists during the 1950s. This super-efficient design was only a fifth as large as an equivalently powerful Minovsky-Ionesco reactor, for this reason it was adopted for use on battle mechs as the standard power plant.

Minovsky Craft System

Since it is made up of charged particles, the I-field is unable to penetrate metal, water, the Earth's surface, or other electrically conductive materials and can be shaped simply by trapping it in an electromagnetic field. Thus, at low altitudes it is possible to generate an I-field cushion between the underside of a vessel and the ground, yielding a gravity-countering buoyancy. This principle is used in the creation of the Minovsky craft system, which allowed a spaceship or heavy ground vehicle to "fly"/hover on Earth. The Principality of NEO was slow to make use of this principle however, the Earth Federation was quick to adopt the system on its Pegasus-class assault carriers. This allowed the Pegasus-class to enter and exit earth's atmosphere and to fly while inside the atmosphere.