Abstract

The hierarchy problem, which questions why the weak force is significantly stronger than gravity, remains one of the most profound puzzles in theoretical physics. Despite various proposed solutions such as supersymmetry and extra dimensions, the lack of empirical evidence from particle physics experiments necessitates alternative theories. This paper introduces a new framework that postulates additional intermediary forces with strengths between gravity and the forces described by the Standard Model. Here, we show that these forces, proportional to n, derived from the reduced Compton wavelength of a particle and Planck’s length, form a structured hierarchy. Our model characterizes these forces, denoted as F_N, with F₁ representing gravity and F₃ representing particle-scale forces. This model aligns with General Relativity for N = 1 and Coulomb’s Force Law for N = 3, and provides empirical support for intermediary forces for N = 2. These findings offer new avenues for research, enhancing our understanding of the universe’s structure and addressing gaps left by existing theories. By integrating these intermediary forces with general relativity, we can further explore their implications on cosmological scales, potentially providing insights into dark matter and dark energy phenomena.

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