The Grand Unified Theory of Classical Physics Resources

The Grand Unified Theory of Classical Physics - Overview
BlackLight technology is built on a new classical approach to solving atoms and molecules: The Grand Unified Theory of Classical Physics (GUT-CP). This approach differs from traditional quantum mechanics, and yields many new predictions and insights.

Q: Who is Dr. Randell Mills?

Dr. Mills is the author of the Grand Unified Theory of Classical Physics. Dr. Mills was awarded a Bachelor of Arts Degree in Chemistry, summa cum laude and Phi Beta Kappa, from Franklin & Marshall College in 1982, and a Doctor of Medicine Degree from Harvard Medical School in 1986. At Harvard, Mills' goal was not to be a practicing doctor, but rather to be involved in the development of medical technology.

While completing his MD, Mills did a year of graduate work in electrical engineering at the Massachusetts Institute of Technology. One of his professors there was Herman Haus, who handed Mills a paper ("On the radiation from point charges") that would be highly consequential for Mills' career. In this paper, Haus derives the conditions by which a distribution of accelerating charges will emit electromagnetic radiation. The converse "classical nonradiation condition" forms the basis of Mills' theory of the atom.

In the atom, electrons are constantly accelerating around the proton in an atomic orbit. Yet, classical physics requires that accelerating charges radiate energy, which would cause the electron to spiral into the nucleus in a fraction of a second. This seminal problem of the stability of the atom was one of the key obstacles physicists faced early in the 20th century, and their inability to solve it led to the construction of quantum theory.

But aided by the Haus' work, Mills solved the structure of the atom using classical physical laws, such that electron orbits were stable to radiation. This allowed Mills to construct a new theory of atoms and molecules that was based entirely on classical physics. And unlike other attempts in the 20th century, the result was not merely a "hidden-variables" reinterpretation of the quantum formalism, but a ground-up reconstruction of atomic theory.

This new model of the atom predicted the theoretical existence of the hydrino, or states of the hydrogen atom that exist below the ground state. To test the existence of hydrinos, and develop commercial applications of them, Mills went on to found BlackLight Power Inc, for which he has served as Chairman of the Board, President, and CEO since 1991.

Randell Mills has authored or co-authored nearly a hundred papers in scientific journals. He has received patents or filed patent applications in the following areas: (1) Millsian computational chemical design technology; (2) magnetic resonance imaging; (3) Mossbauer cancer therapy (Nature, Hyperfine Interactions); (4) Luminide class of drug delivery molecules; (5) genomic sequencing, and (6) artificial intelligence.

Q: How does the GUT-CP describe nature?

According to GUT-CP, nature is classical. Electrons, when bound in an atom, are considered to be discrete spherical shells of charge that completely surround the nucleus. These shells, called electron orbitspheres have a complex pattern of motion on the surface that gives rise to electron spin. They obey classical physics, and are stable according to the nonradiation condition, a Maxwellian condition under which charge/current distributions do not radiate energy. This solves the problem that has plagued atomic physics since the Bohr model of the atom: how an electron, continuously accelerating in the coulombic field of the proton, is able to remain in a stable orbit.

This approach is extended to solve multi-electron atoms and molecules. In multi-electron atoms, bound electrons group into a series of concentric shells, each of which is an atomic orbital and may contain several electrons. In molecules, the electrons stretch over two nuclei to form a prolate spheroidal shell with the nuclei at the foci. Each reaches a minimum energy configuration for the system, controlled by Maxwellian and Newtonian forces.

From with this frame of reference, GUT-CP unwinds many of the mysteries of quantum theory. GUT-CP is not a "hidden variables" interpretation of the formalism of quantum theory, rather, it is a new classical theory based on Maxwell's Equations and Newton's Laws. It explains canonical experiments of quantum mechanics such as the double-slit experiments and the Aspect experiments classically.

Q: What does the GUT-CP predict? How has it been validated?

The GUT-CP is a confirmable theory, meaning it makes many claims about nature that can be confirmed or denied through experiment. The GUT-CP predicts thousands of atomic and molecular parameters that match known data to high accuracy, often to much higher accuracy than predictions by quantum mechanics. Further, several data sets produced by the GUT-CP have never been calculated before.

Data sets include the electron spin, g-factor, ionization energies of 1-20 electron atoms and ions (400 states); the state lifetimes and line intensities of hydrogen; the excited states of helium; the relationships between the masses of fundamental particles; the bond distances, energies, angles, and dipole moments of over 800 molecules; and the parameters of a variety of extended solids. From the molecular theory, BlackLight has launched a molecular modeling subsidiary, Millsian Inc.

The GUT-CP also predicted some phenomena new to science. In 1995, it predicted that the universe was accelerating in its expansion, and predicted the rate of acceleration, which was confirmed experimentally later that decade, much to the surprise of the scientific community. The GUT-CP also correctly predicted the mass of the top quark and the lack of time dilation in redshifted quasars.

The GUT-CP also predicts the existence of hydrinos: a series of stable energy states of the hydrogen atom that exist below the "ground state" that observations support is the identity of the dark matter of the universe. BlackLight is engaged in experimentally characterizing hydrinos and developing the technology for commercial use. Hydrinos may also react to form hydrino gas and hydrino hydride compounds (HHC's), both with very high binding energies.

See the Molecular and Atomic Physics Summary Tables for predicted vs. observed values. See a list of theoretical papers published in journals, or visit our technical papers page.

Q: Do hydrinos violate conservation of energy?

No. Hydrinos form when hydrogen atoms resonantly exchange energy with another atom (a catalyst) capable of single or multiple ionization at integer multiples of 27.2 eV. This process relies on multipole coupling between the hydrogen atom and the catalyst. The hydrino then emits a photon and drops into a lower energy state, in which the electron is closer to the proton, forming a higher binding energy hydrogen atom. Energy is conserved in this process. The resulting hydrino atom cannot be converted into a normal hydrogen atom without the addition of energy equal to that released by the formation of the hydrino.