Quantum Electric Gravity: Direct Experimental Verification

Quantum Electric Gravity (QEG) is a new theory of quantum gravity predicated on EM and QM. 
Unlike the classical Newton and Einstein’s General Relativity theories, QEG can derive gravity 
from the fundamental pillars of EM, QED and QCD, and can potentially reveal the origin and 
root cause of gravity. The long-range bi-directional EM–QED force, mediated by force-carrier 
messenger particles between charge entities, give rise to continuous QM quark vibrations. The 
QCD gluon force imposes asymmetrical restrictions on these vibrations leading to a net energy
change that can account for the force of gravity due to energy conservation. To date, most 
theories of quantum gravity like string theory, loop quantum gravity and others are not amenable 
to direct experimental verifications, largely due to their high level of abstractions that lacks 
significant connection to fundamental physics. In contrast, QEG is fundamentally different in 
many respects, including the following. First, it is theoretically derived from the fundamental 
pillars of QM, leading up to the complete QEG equation comprising QCD binding energy, QED 
quantum probability, and EM parameters and entities. Second, the QEG equation and parameters 
are experimentally verifiable and testable by well-established laboratory experiments. This leads 
to the interesting outcome that appears to support and corroborate QEG with a relatively high
level of confidence.