Stringnoides o cordoides y singularidades bosónicas versus modelo del átomo de hidrógeno

Abstract

This paper addresses bosonic string theory and proposes a new conceptual extension: bosonic singularity and stringoids. Bosonic string theory posits that elementary particles are not points, but vibrating strings in a 26-dimensional space-time. This theory, although limited to the realm of bosons and including tachyons, has been a fundamental pillar for the development of more complex models, such as superstrings. One of the major advantages of this formulation is its ability to smooth out traditional space-time singularities, allowing for a quantum description of the universe.

The concept of bosonic strings, derived from bosonic theory, is introduced as a specialized category of strings that could be focused on generating bosonic fields or modulating the structures of the quantum vacuum. From this basis, the notion of a bosonic singularity is raised, a state in which bosonic modes (such as strings or gauge fields) concentrate or diverge, generating nonlinear or critical effects. This type of singularity is not related to infinite curvature, but to an extreme concentration of energy that gives rise to nonperturbative transitions.

The bosonic singularity is inspired by phenomena such as conifold transitions and bosonic condensates. This new concept aims to broaden our understanding of quantum physics and the structure of the vacuum, potentially opening up new avenues for understanding fundamental interactions and the evolution of the universe.