Iron Man 1 Highly Compressed Pc Game

[Gaynelle Alnutt]

Forthe context, a group of first-gen mutants got together, and seeing their power could loosely represent the greek pantheon, they decided to spin their super-identity around the concept. The metal bender is Hephastos.

The mutant in question, on top of being extremely strong, can "shrink" (and un-shrink) metal, while making it retains its mass. He creates several tons oversized weapons, then shrink them and use them in combat.

From my basic understanding of physics, you could theoretically accomplish that by forcing atoms to stick closer to each other. The process would increase the density (so mass is conserved) and produce a lower volume - equal weight object.

Thanks for pointing out any mistakes in the reasoning or the consequences, and please excuse any misuse of physical terms (I'll be happy to correct if you point it out). The exact process by which atoms are forced to stick closer to each other is the hand-waved part.

Since you have what is basically a human doing the shrinking & expanding of the metal, the obvious means is a kind of magic. As you already said: the mutant squeezes the metal so that the atoms press closer together, then reexpands the metal to its normal dimensions.

While not realistic per se, as pointed out by the answer of CKA, it can work as an "arbitrary" superpower, as long as it is consistent. So, what would happen if this Hephastos actually had the power of squeezing metal atoms together by thousandfolds if not millionfolds? He would create degenerate matter, the stuff white dwarf stars are made of.

The compression would heat the metal to immense temperatures, so I will assume that the extra heat is temporarily stored by the power itself, and put back when it stops acting. Heat transfer depending on surface, it may have an immense heat capacity for its size, assuming the stable degenerate matter somehow keeps working like a metal in that regard.

If his power has an "inertia", and the bauble only slowly expands back to its original size once the effect stops, he can still use the expansion to break pretty much anything, but in the way of a hydraulic piston instead of a bomb. Inversely, the compression itself may be used to crush things with irresistible force, possibly up to nuclear fusion level. If you want to avoid this, the compression or expansion effect may be resisted externally due to how the power itself works - if expansion is limited, an object could be kept indefinitely in its compressed state if, for example, encased in something hard.

Baubles massing several tons are extraordinarily scary things. They will fall through the ground if you leave them there. So as Hephastos is strong enough to wear it, he is also strong enough to throw them, and there is nothing (barring other superpowers) that can survive that level of armour-piercing. If he needs less armour-piercing and more impact damage, simply compress it less, to have more contact surface for the same projectile mass and speed. If he can compress and throw shrapnel, armor-piercing dust would also be a terrifying weapon. And of course, a bauble knife or cutting wire will cut through anything. Conversely, compressed armor will stop any non-superpowered attack with sheer mass and density.

Also note that Hephastos is not only immensely strong, to be able to carry those, he also has an incredibly resistant skin (and clothes), or some sort of telekinetic powers. Otherwise, the baubles will go through him as easily as through any ordinary matter. (This type of required secondary superpower is similar to how Superman can grab a car by its bumper without ripping said bumper apart.)

Metals are to some degree compressible, and they may be compressed even further undergoing some phase transitions to denser modifications. Plutonium is a metal famous for having many modifications and a more dense modification created under high pressure is one ingredient of a nuclear bomb.

However, under given conditions (pressure and temperature) only one modification is stable and the other modifications are usually unstable or in rare cases meta-stable (like diamond, a meta-stable modification of carbon/graphite under normal conditions). A phase transition is always mass preserving and the chemical identity of the material is unchanged, but the stability of an object is usually not guaranteed and sharpness of weapons is surely not preserved.

The best your mutants can have are weapons made of very dense meta-stable metal causing heavy violence to the victims and breaking weapons made of low density metals. Live transformations from small to big or vice versa won't work. Depending on the tech level, those very heavy weapons are probably copy-protected (but still can be conquered or stolen by non-mutants).

I'll be looking at the energy side of this with my admittedly very cursory understanding of degenerate matter, because it's pretty interesting. If you want to compress metal down to small, but still macroscopic sizes it's probably alright to disregard anything to do with the nucleus and just look at the Fermi energy of the electron gas within the metal. The energy per electron is $E = \hbar^2 (3\pi^2*Electron Density)^2/3/2me $ in a Fermi gas. According to this table -astr.gsu.edu/hbase/Tables/fermi.html the value for iron would be $17*10^28$ free electrons per cubic meter. Which gives us about $11 eV$ of energy per free electron. If you want to cut the iron's density by a factor of say, ten, we have ten times higher electron density and an increase in energy of $10^2/3$, ca. $4.64$. So each free electron has an energy of about $51eV$ now. As said before, there's $17*10^28$ free electrons in a cubic meter of iron. Each of those has 40 additional electronvolts of energy now, which comes up to a total of $1.09 * 10^12 J$ of energy, or $260 t$ of TNT equivalent. Yep, a block of metal is practically a small nuke. Formidable indeed if your mutant can also spontaneously decompress metal.

To answer 1): The density in a White Dwarf is a hundred thousand times larger than iron, but the nuclei still stay intact in the degenerate electron gas. Iron will stay iron even for a very high compression.2): Yes, I see nothing that would indicate otherwise. It's just very dense.3): Realistically it'd be a white hot nugget of extremely high temperature, see math above. Having it be stable requires handwaving. It makes intuitive sense that extreme density would also result in an increase in durability though, there's simply more mass to move out of the way if someone wants to punch a hole into it. Another cool property you could give these metals is superconductivity. Highly compressed hydrogen is theorized to turn into a superconducting metal for example, so it's not a farfetched idea to apply that here too. There's all kinds of cool stuff coming with that, like levitating in magnetic fields.

Don't forget about inertia. You must push as hard to move a bauble as if it were its normal size & every movement continues in its direction & rotation until you put in the same energy as you did to get it started. (Consider handling a piano via an attached bracelet charm.) This also means that the force & pressure to push it and get the friction to twist it is increased.

On the other hand, you really don't need weapons or metals, you can just compress rocks or for that matter marshmallows, because when you throw them the target is going to have to donate the same amount of energy at the same pressures as you.

If your weapons are made of a pure metal there shouldn't be much issue I would suspect, but if you have some form of contaminant I would imagine it would work like squeezing water of out of a sponge, the carbon for example leaking out of the metal because it needs to make room for the lattice of the metal atoms that are squeezed together by the power. Or you follow the astronomers interpretation of metal and that's basically everything is a metal that's not hydrogen and helium. But even then the mixing of materials could pose problems due to different atomic sizes when compressed that hard to reduce size.

Assuming the magic applies uniform pressure causing the metals to shrink the metals could "bounce" out like a spring when it's uncompressed too fast. Your mutant will need patience in order to prevent growing damage when expanding.

The reason metals have such low strengths is because of imperfect atomic structures in the crystal lattices which make them up. Often a row of atoms will stop mid crystal and a gap is created in the atomic structure. These gaps act as huge stress raising points known as dislocations.

So basically his weapons need to be metal perfect, without any imperfections. That would make his materials of course extremely valuable for the scientific community and could be a nice source of income.

His swords or metals could make for a nice bomb. Imagine a metal slab the size of a pellet, but actually is the size of a brick. He throws it at the enemy and as it lands there he releases his magic.The spring effect from the sudden pressure release will probably tear the metal apart sending shrapnel flying everywhere, and depending on the rate of expansion send a shock wave through the air that will rupture internal organs.

An atom is composed of a nucleus surrounded by an electron cloud. The nucleus is about 10e-15 m in size (about 10e-5 or 1/100,000 of the atom). A good comparison of the nucleus to the atom is a pea in the middle of a racetrack.

The nucleus is composed of protons (positive) and neutrons (zero). There is a nuclear force which is (mostly) attractive and acts between protons and neutrons, and is stronger than the repulsive electric force.

The size of atoms, the size of molecules, and the distance of metal atoms in the crystal grid are determined by the size of the electron hull, which in turn depends on the interaction of the electrons with each other and with the nucleus.

Electrons around nuclei behave a bit like three-dimensional standing waves, comparable to a resonating surface, but in space. The wave's shape is determined by the electric charge of the electron and proton, the mass of the electron, its energy and the vacuum permittivity. The latter in turn is connected to the light speed; higher speed of light would decrease the permittivity which in turn would increase forces between charges, if I understand correctly. Let's assume that higher forces would result in smaller atoms and denser crystal grids. All your hero needs to do is to locally increase the speed of light. I would think that that is equivalent to locally speeding up time. Easy ;-).

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