| Classification | Subatomic Particle |
|---|---|
| Composition | Elementary Particle |
| Statistics | Fermionic (Unique) |
| Symbol | χ |
| Antiparticle | antimanon |
| Discovered | 1988 |
| Mass | 1.79769313(308)×10−24 kg |
| Mean lifetime | 5.139860(72)×102 s |
| Decays into | itself, γ, ν and (rarely) c |
This article is not real. Don't take anything said as reality.
Chions are a special particle type, which only interact with fermions, gravity and itself. Since Chions are common, piles of them can be found and made. The material they produce are called Chionium. It has no spin, or any other properties other particles have. It simply has three properties called hue,phase and power. The hue of a chion is independent and unique to every chion.
Chions are relatively stable, the half life of a Chion is about 3 years and 2 months. This decay usually yields neutrinos and mainly photons. If a Chion has enough power, it can also produce a charm quark or even split itself. This instability appears to not be from an inherent instability in the chion itself, but rather because of the disturbance from other particles. This has been observed as chionium becoming brighter on touch.
Chions, like all elementary particles has an antiparticle called the Antichion. Antichions have negative power, and decay into the charm antiquark, antineutrinos and an antiphoton (which is a regular photon but with the opposite momentum and 180° out of phase).
Chions were initially called Chromons, but this name was slowly disused after the 1990s. They are denoted by the greek symbol chi (χ).
Chions have a high mass, about 1.00804 TeV/c2, which is more than 1000 times the mass of a proton. This means that the material is incredibly dense.
Chions have two forces: a force that attracts one chion to another, and another that repels either when they get too close. The repelling force overtakes at about 32.6045 picometres. This makes chionium a very dense but compressible powder. The density at the neutral point where the material settles is about 1 287 310 kg/cm3, making it over 30 times denser the higher predictions for Hassium, currently the highest predicted density for a regular material. This makes chions very valuable.
They are usually produced in supernova, and then later split themselves apart into many many particles.
History edit
Chions were theorised to exist since the 1950s, but only in 1988 with the help of observations from space was their existence confirmed. At first they were called Chromons due to them producing various colors, but this name was replaced with Chions in the 1990s, and slowly phased out of use.
Chions were later produced in particle colliders, and then regular productions of lower-power chion was found by using extreme forces to force high-energy plasma into generating chions.
Chion Sources edit
Chions can be formed from various sources, most of them involving high-energy interactions between protons and neutrons. The mechanics of how chions come into existence aren't quite understood. All we know is that more violent reactions lead to more powerful and numerous chions.
Chion Decay / Power edit
Chions decay based on their power. Power is a chion-specific property which can be gained from the surroundings, either during the creation of the chion or later. Usually this source is light, when a photon directly comes into contact with a chion, it increases the chion's power. When matter is pushed hard enough into a chion, the repellent force will again be dominated by the attraction force and turn the matter into a lot of power.
This power is eventually given out as the chion decays.The mean lifetime of a chion is calculated based on a chion with a power of 1, but usual chions have power in the range of billions.
To be more specific, the power of a chion is increased by a neutrino (depends on type and mass), by a certain amount if it absorbs a photon which is based on the energy of a photon. Interactions with matter aren't very well-known, but it is estimated to be 4 000 000 / atom of carbon (error of 30 percent).
Chions release their power using decay. Neutrinos cost the same as the gain that would be gained from the neutrino, and photons work the same way., althout the photon will not be of the same frequency due to the hue. a charm quark is estimated to have a power deficit of 200 000 (error of 10 percent).
Once the power of a chion reaches zero, it disappears.
The emission chance of a particle depends on the power already present in a chion. For power values less than 10 000, the dominant emission is neutrinos. For higher power values, the dominant emission type is photons which increase in frequency and always stays the dominant emission type after 10 000. For power values higher than 1 000 000 000, charm quark emission begins regularly ocurring.
Chions with very high (>1020) power , this power can generate another chion. The power is not split evenly, and more often than not seems to follow a gaussian distribution. The chances of a split occurring increase as power increases.
Power is defined as 0.07 meV.
Hue and Phase edit
A chion's main property however is it's hue, which is the frequency at which the photons emitted are in. Phase is the phase of the emitted photon. This makes chions useful for emitting very specific wavelengths or phases of light. Hue and phase are simply written out as they would be: in nanometers and degrees.
The most common hues are in the middle of the visible spectrum. Hue also affects the weight of a chion very slightly. A 500 nm hue chion weighs 1.00804 TeV/c2, which is the standard weight used in most cases but a chion at 200 nm weighs about %0.2 more. The smallest hued chions in the gamma ray range can weigh up to ten percent more. This is how chions can be sorted using gravity only, since chions within of themselves are frictionless and will sort themselves by hue very quickly. Fascinatingly, power doesn't seem to affect the mass of a chion.
Uses edit
Chions currently don't see much real use. They can be produced in large quantities (>1g) but since chionium decays relatively quickly, it's often too short-lived for most serious usage. It currently is made in large quantites and sometimes stuck onto sand or other materials via Chion Integration.
They have been put into bullets and rounds by amateurs, and it's highly sought after in these circles due to it's extreme density.
Chionium is thought to be completely safe at low power levels, but at high levels the high brightness and charm quark generation is a reason for concern.
Chions have also been used for production of high-frequency light or very specific frequency light sources. Since the amount of matter eaten to produce energy is indistinguishable from nothing, sometimes these lights are fed using actual matter. Although this has sometimes gone wrong.
Chionium is extremely heavy to the touch, and people who have touched it say that it's similiar in feeling to water. Chionium is technically a superfluid, since it has no friction. It also in most situations doesn't stick to matter. The force at which it sticks is highly relevant to the hue of the material: higher frequencies are more likely to absorb matter. This also means that it's often brought into schools for demonstration.
Some extreme drug experiments involving chionium have also been conducted. The results have been that chionium does not interrupt the natural processes at all.