Gravity has traditionally been described by two prevailing paradigms: (1) Newton's law of universal gravitation as an attractive force (Newton, 1687), and (2) Einstein's general theory of relativity, which interprets gravity as the curvature of spacetime (Einstein, 1915). Although these frameworks adeptly account for numerous macroscopic observations, they fall short in explaining gravitational phenomena at quantum scales. To date, no empirical evidence for quantum gravity has been observed, and the postulated graviton—integral to extensions of the Standard Model of particle physics—remains undetected (Weinberg, 1967). This discrepancy positions gravity as one of the most profound enigmas in contemporary physics.This study introduces a novel model wherein gravity arises from the perpetual absorption of Virtual Energy Particles (VEPs) by atoms, essential for sustaining the stable orbital configuration of electrons. The incessant uptake of these particles induces a directional flux toward the atomic nucleus, manifesting as a gravitational field. Within this paradigm, gravity transcends mere attraction or geometric distortion, emerging instead as a fundamental mechanism for energy redistribution that underpins atomic integrity and cosmic equilibrium.The concept of virtual particles is substantiated by quantum vacuum fluctuations (Heisenberg, 1927), Feynman diagrams in quantum electrodynamics (Feynman, 1949), and empirical phenomena such as the Casimir effect (Casimir, 1948). Diverging from classical mechanics and general relativity, this model conceptualizes gravity as a flux of virtual particles, reconciling quantum microscopic dynamics with macroscopic cosmic behavior. Accordingly, this theory posits that VEPs serve as the primary mediators of gravitational fields and atomic stability, providing a prospective avenue for unifying gravity across disparate scales.