Why does copper spontaneously demagnetize?

Really in depth explanation about how nuclear physics in terms of fusion controls the magnetic properties of elements such as copper and iron. I just made this up from my mind today, but if you read carefully you'll understand it is actually for sure correct. I don't even know if this information exists elsewhere, but it is correct for sure. Did I find something first? Probably not. Yeah.... but still super cool. I made this myself. Best thing I've done in a while.

The magnetic field is parallel to the electric field since both things are forms of rotation and differing forms of rotation are always partitioned in different spaces because their directions are orthogonal and therefor not additive in terms of a resultant force, so their rotations traverse different paths from their onset. This however this needs to be contrasted with the fact that when an electric field produces an acceleration along some path it is causing perpendicular motion which is change in linear momentum from the electric fields angular momentum so the acceleration of charge acts through the magnetic field to produce linear trajectory since the dipole is intrinsic and partitions the two forms of rotation always in a pair due to Newton's third law and the sum of the two differing rotations results in an angular momentum for the resultant magnetic field. Mass as a six dimensional object can only act on spacetime or through the displacement of charge by spacetime expansion. This means heat must act through the magnetic field to produce outward change in linear momentum from the electric field constituent angular momenta in any circumstance since the rotational directions determine the direction of acceleration in the field and the magnetic field is always present with that acceleration and parallel fields would not have the ability to act on one another since they are essentially divergent and this means the linear momentum starts first at the magnetic fields presence and is the method for that perpendicular transfer of momentum. So I would assume heat itself is the conversion from angular momentum of a magnetic field to linear momentum of the partitioned electric fields and the behaviors that result from the directions of rotations of those fields as they effect the electrostatic forces we see.

It then follows that an endothermic process is one that cools the surrounding system and cooling is a process that partitions charge by causing loss of linear momentum or kinetic energy that acts through the magnetic field, but if the magnetic field loses linear momentum then it gains angular momentum and this is fine because the two are equal and opposite reactions since the angular momentum is simply the generation of a force through a wave and the linear momentum is the transmission of a force caused by a wave which means the transmission of the linear momentum to the angular momentum can just be seen as a matter of newtons third law and this means elements that were fused at or past the iron peak which are endothermic fusion processes are elements that have converted linear momentum acting normal to a magnetic field to produce angular momentum of that magnetic field which causes it to act as a force for a dipoles intrinsic inertia which means the fusion has caused an energy barrier to the dipoles misalignment and heat is needed to exceed that barrier and cause demagnetization. This is why Iron which is heavy and has many protons and is past the iron peak and is therefor the result of such endothermic fusion has the ability to maintain magnetization since its ground state can then be understood as one that requires the addition of heat as charge leaves the iron because the displacement of charge from the iron has behind it a magnetic force that is of a normal vector which produces outward linear momentum that is less than the angular momentum of the dipole and therefor attenuates faster than the charge is displaced as a normal vector acting on that partitioned charge which means it doesn't produce heat as the charge leaves the iron since heat is an outwardly accelerating process that causes change in kinetic energy through the magnetic fields normal vectors action on the electric field as the result of the expansion of spacetime.

Exothermic fusion is a process that causes the magnetic fields normal vectors magnitude to increase as the magnetic fields angular momentum decreases because heat is the displacement of charge and a decrease in angular momentum is like phase cancellation and phase cancellation produces a normal vector change in magnitude because of Newton's third law and that means the magnetic field that results from the dipole acts with greater normal vector magnitude outward in an accelerating fashion due to the consequential increase in density of mass which results when two oppositely rotating objects close in distance and this means when a substance that was formed from exothermic fusion loses the presence of the strength of an electric field the action of that field that aligns the dipoles is overcome by the normal vectors magnitude to the magnetic field which produces kinetic energy since the electric field was needed to increase the angular momentum of the magnetic field which was how the dipole maintained its alignment and due to the law of conservation of momentum when the charge leaves the exothermically fused substance the displacement of that charge causes the production of heat which spontaneously demagnetizes the substance again and this process may only be changed if the substance can be cooled sufficiently enough to reduce the linear momentum of the magnetic field such that the displacement of the charge no longer reduces the angular momentum so much that it doesn't allow for the inertia of the dipoles to maintain the dipoles planar alignment.

In shorter words that are much more familiar and less theoretical sounding because I'm basically just producing that stuff from my own theories the reason copper doesn't magnetize is that its ground state is exothermic which we know from the fact that the fusion is not after the iron peak where endothermic fusion occurs. This means as the charge leaves the wire the copper can't absorb heat because the fusion displaced enough charge on its boundary to cause heat as a result of that displacement which means to form a dipole the copper needs to have the magnetic fields angular momentum increased to increase the inertia of the dipole such that it exceeds the ground state exothermic kinetic energy of the linear momentum that the magnetic field has that as mentioned spontaneously misaligns the dipoles because the inertia does not naturally overcome the kinetic energy from the linear component.

So in closing I'd like to leave you with a question, namely: can you relate an increase the strength of a magnetic field to linear velocity using general relativity?