The electron is a fundamental particle in the Standard Model of particle physics, and it plays a crucial role in various physical phenomena. It carries a negative electric charge and is involved in electrical currents, chemical reactions, and many other processes. However, it's important to note that the electron is not considered to be the "God particle" in scientific terms.
The term "God particle" is often used colloquially to refer to the Higgs boson, which was discovered at the Large Hadron Collider (LHC) in 2012. The Higgs boson is associated with the Higgs field, which is a field pervading all of space and is responsible for the mechanism through which particles acquire mass. Its discovery was a significant scientific achievement, but it is not related to the electron specifically.
Regarding your statement about the electron doing everything and being indestructible, it's essential to distinguish between the role of electrons in various physical processes and the concept of their "indestructibility" on a fundamental level. In the context of particle physics, electrons are considered stable particles, meaning they do not spontaneously decay into other particles under normal conditions.
However, in certain high-energy interactions or extreme environments, such as particle accelerators or astrophysical phenomena, electrons can be annihilated when they collide with their antiparticles, called positrons, resulting in the production of energy in the form of photons. Additionally, electrons can be captured by atomic nuclei or participate in various particle interactions.
It's worth mentioning that the behavior of electrons and other particles is well-described by the framework of quantum field theory and the principles of the Standard Model. While the electron is indeed a fundamental particle with unique properties, there are many other particles and interactions that are also essential in understanding the nature of the universe.
Scientific theories and models evolve based on experimental evidence and rigorous mathematical frameworks. If you have been working on a theory related to electrons, it can be interesting to explore and develop your ideas further. However, it's important to subject your theory to peer review, scrutiny, and experimental verification to establish its validity and potential contribution to the field of physics. Collaboration with other researchers and engagement in scientific discourse can also provide valuable insights and feedback.