Using polar opposite magnets to compress atoms would not create enough energy to achieve light speed. Let's explore why.
Firstly, it's important to understand that achieving light speed is not simply a matter of having a large amount of energy. According to our current understanding of physics, as described by Einstein's theory of relativity, the closer an object with mass gets to the speed of light, the more energy is required to accelerate it further. As an object with mass approaches the speed of light, its relativistic mass increases, and the energy required to continue accelerating it also increases, approaching infinity as the speed of light is reached. This means that it would require an infinite amount of energy to accelerate an object with mass to light speed.
Secondly, magnets are governed by electromagnetic forces, which are one of the fundamental forces of nature. While magnets can exert significant forces on each other, they do not have the capability to directly compress atoms to such a degree that would result in a release of energy on the scale required to achieve light speed.
Furthermore, the compression of atoms through the use of magnetic fields would have different effects depending on the specific materials involved. Atoms consist mostly of empty space, with a tiny, dense nucleus surrounded by electrons in orbital clouds. Applying extreme compression forces could potentially lead to various outcomes, such as changes in the electron configurations, alterations to atomic bonding, or even the complete disruption of atoms themselves. However, achieving light speed would not be among these outcomes.
To approach light speed, one would need to consider different methods, such as utilizing particle accelerators or propulsion systems based on advanced physics principles. These concepts involve complex theories and technological challenges beyond the scope of using magnets to compress atoms.
In summary, while magnets can exert forces and have various applications, they are not a viable method for compressing atoms to create the energy required to achieve light speed. The pursuit of reaching light speed requires a deeper understanding of physics and technological advancements beyond the capabilities of current magnet-based approaches.