What if gravity and electromagnetism share a single mechanical cause?
Gravium theory offers a bold alternative to modern physics—a mechanical explanation for gravity and electromagnetic forces, rooted in a rigid universal medium.
What Is Gravium Theory?
Gravium theory—formally known as Gravium Rigidity and Atomic Contraction—proposes that gravity and electromagnetism arise from a shared mechanical origin: a rigid, universal medium called gravium. While the concept of a medium may sound reminiscent of 19th-century ether theories, gravium theory addresses the very shortcomings that led to their abandonment.
Unlike classical ether models, this theory explains the outcome of the Michelson–Morley experiment through the combined effects of a Prime Frame of Reference and atomic contraction—a concept unique to this framework. Atomic contraction also plays a key role in other predictions of the theory and helps unify seemingly unrelated physical behaviors under one coherent model.
Gravium theory challenges long-standing assumptions in both special and general relativity by reintroducing mechanical explanations for force propagation, while remaining mathematically testable and physically meaningful. It invites both scientists and curious thinkers to reconsider the foundations of physics—not just through equations, but through a deeper understanding of what those equations represent.
Why Gravium Theory Matters
Modern physics has increasingly emphasized abstract mathematics over physical understanding. Concepts like curved spacetime and quantum fields are mathematically elegant, but they often lack intuitive, mechanical explanations. Gravium theory takes a different path.
This theory addresses one of the biggest unresolved challenges in physics: action at a distance. Rather than ignoring this mystery or burying it in equations, gravium theory offers a mechanical and intuitive solution—one that is accessible without requiring advanced mathematical background.
By proposing a rigid medium responsible for both gravity and electromagnetism, gravium theory restores a sense of physical reality to forces that are too often treated as mathematical abstractions. It reclaims the idea that physics should describe how the universe actually works—not just what the equations say. In short, it puts the physics back into physics.
Explore the Book: Action at a Distance
Action at a Distance presents the full development of Gravium Rigidity and Atomic Contraction, offering a step-by-step breakdown of the theory, the mathematical foundations behind it, and the philosophical implications it raises.
The book challenges the core assumptions of special and general relativity, proposes a mechanical unification of gravity and electromagnetism, and introduces an original experiment to test its predictions. Written for both scientists and intellectually curious readers, it balances mathematical rigor with accessible explanations—each chapter concludes with a summary to help clarify key points.
Whether you're a physicist open to new ideas or a general reader drawn to the deeper questions of the universe, Action at a Distance invites you to consider a radically different way of understanding physical forces.
This book has been taken offline. I am working of revisions of the book and when they are complete I will republish the book.
About the Author
Eugene Eddlemon is an independent researcher and lifelong student of physics, mathematics, and the foundational questions that shape our understanding of the universe. Driven by both intellectual curiosity and a conviction that science should be grounded in logic and physical meaning, he developed Gravium Rigidity and Atomic Contraction as an alternative to the abstract frameworks of relativity and quantum field theory.
His book, Action at a Distance, reflects over a decade of thought, refinement, and engagement with classical and modern physics. Eddlemon brings a mechanical and intuitive lens to fundamental forces, challenging long-held assumptions and proposing testable alternatives grounded in reason and observation.
He writes not only for scientists, but also for curious readers who believe that the universe can—and should—be understood through clear, physical principles.