Author(s)

Walter J. Christensen Jr.^1,2

¹Department of Physics and Astronomy, Cal Poly Pomona University, Pomona, USA.
²Department of Physics, Cal State Fullerton, Fullerton, USA.

Though not well-known, Einstein endeavored much of his life to general-relativize quantum mechanics, (rather than quantizing gravity). Albeit he did not succeed, his legacy lives on. In this paper, we begin with the general relativistic field equations describing flat spacetime, but stimulated by vacuum energy fluctuations. In our precursor paper, after straightforward general relativistic calculations, the resulting covariant and contravariant energy-momentum tensors were identified as n-valued operators describing graviton excitation. From these two operators, we were able to generate all three boson masses (including the Higgs mass) in precise agreement as reported in the 2010 CODATA (NIST); moreover local, as-well-as large-scale, accelerated spacetimes were shown to naturally occur from this general relativized quantum physics approach (RQP). In this paper, applying the same approach, we produce an n-valued Coulombs Force Law leading to the energy spectrum for atomic hydrogen, without assuming quantized atomic radii, velocity and momentum, as Bohr did.

General Relativity, General Relativizing Quantum Mechanics, Fundamental Constants, Coulombs Force Law, Atomic Hydrogen Energy States, Bohr Radius, Higgs Mass, Bosons, Mass Hierarchy, Rydberg Constant, Hawking Radiation

Christensen Jr., W. (2015) Relativized Quantum Physics Generating N-Valued Coulomb Force and Atomic Hydrogen Energy Spectrum. Journal of Modern Physics, 6, 194-200. doi: 10.4236/jmp.2015.63025.