Manifestation of Quantum Forces in Spacetime: Towards a General Theory of Quantum Forces

TL;DR

This paper proposes a new theoretical framework, the quantum force wave equation, that describes quantum forces as emergent phenomena from interactions between quantum particles and curved spacetime, unifying quantum mechanics and gravity.

Contribution

It introduces the quantum force wave equation as a novel, unified approach to quantum forces in curved spacetime, extending current theories and offering new insights into quantum gravity and high-energy physics.

Findings

Establishes a dynamic relationship between quantum states and spacetime geometry.

Provides a unified description of quantum forces in curved and dynamic gravitational fields.

Lays groundwork for future research in quantum gravity and cosmology.

Abstract

This study introduces the quantum force wave equation (QFWE) as a general theory of quantum forces, a novel framework that redefines quantum forces as emergent phenomena arising from the interaction between quantum particles and curved spacetime. By coupling wavefunctions to spacetime curvature and gauge fields, the theory establishes a dynamic, bidirectional relationship between quantum states and spacetime geometry. This approach provides a unified description of quantum forces in highly curved and dynamic gravitational fields, extending beyond the limitations of existing theories. The theory offers fresh insights into quantum gravity, quantum field theory in curved spacetime, and particle physics in extreme conditions, serving as a versatile tool for exploring the interplay between quantum mechanics and spacetime structure. This work lays the foundation for the advancement of high-energy physics and cosmology in regimes where spacetime curvature is fundamental.