4D Quantization of Metric Matter-space-time in Steady Chemical Structures

Abstract

Coulomb and Newton "fundamental forces" are consequences of the nonlocal organization of energy currents, and these consequences with inverse square accelerations cannot change the steady quantization of an extended charge, including its metric distributions in the chemical bonds of micromolecules, mesoscopic clusters and macroscopic superconductors. Based on the Bohr-Sommerfeld quantization of charged particles, there are no theoretical grounds for developing SQUID-type instruments to calculate electric and gravitational interactions-consequences with quantum precision. The self-coherent nonlocality of isolated molecules and holonomic crystals maintans the metric organization of curved space-time with material 3D space under Euclidean geometry. The metrical shaping and 4D quantization of the elementary material continuum  quantitatively introduce the Sommerfeld constant and the Plank length.