by Musa D. Abdullahi | Apr 15, 2014 | Paper

For an electron of mass m and charge e moving at time t with velocity v and acceleration d v /dt in an electric field of magnitude E, the accelerating force is proposed, in accordance with Newton’s second law of motion, as F = eE(c – v)/c = m(d v /dt). The...
by Musa D. Abdullahi | Apr 15, 2014 | Paper

An electric charge Q of mass m, in the form of a spherical shell of radius a, moving at time t with velocity v and acceleration d v / d t, generates an electro-dynamic field X proportional to the acceleration. The field X acts on the self-same charge Q to produce an...
by Musa D. Abdullahi | Apr 15, 2014 | Paper

An electric charge Q of mass m, in the form of a spherical shell of radius a, moving at time t with velocity v and acceleration d v / d t, generates an electro-dynamic field X proportional to the acceleration. The field X acts on the self-same charge Q to produce an...
by Musa D. Abdullahi | Apr 15, 2014 | Paper

Neutral bodies are considered as composed of equal numbers of positive and negative electric charges whose fields exist in space but cancel out exactly everywhere except at the location of charges. Mass and Newton?s law of gravitation are expressed in terms of the...
by Musa D. Abdullahi | Apr 15, 2014 | Paper

An electric charge Q of mass m, in the form of a spherical shell of radius a, moving at time t with velocity v and acceleration d v / d t, generates an electro-dynamic field X proportional to the acceleration. The field X acts on the self-same charge Q to produce an...