NET KINETIC ENERGY DIFFERENTIAL GUIDANCE AND PROPULSION SYSTEM FOR SATELLITES AND SPACE VEHICLES
Initially, in deep OCTM space two basic monopoles, being of opposite or like charge, attract and/or repel each other according to Coulomb's law of charges. When two oppositely charged basic monopoles are close enough to each other and are traveling at low enough relative velocity so their fields of influence, according to Coulomb's law of charges, are strong enough to overcome their relative net vector linear momentums, according to Newton's three laws of motion, the two basic particles link forming the smallest postulated basic dipole of matter, Figure 1.
When two oppositely charged monopoles of matter attract each other as above, they travel pursuit courses toward each other at an accelerating relative velocity. Occasionally, the initial net vector linear momentum of the two basic particles is such that the initial pursuit courses are on perfectly centered straight lines resulting in a perfect, direct, head-on collision. Such a perfect, direct, head-on collision results in an enormous release of kinetic energy, raising the temperature of the particles to the temperature range of some of the particles of matter in the corona of the Sun.
Most of the particles of matter, attracting each other as above, have initial relative net vector momentum paths that are not on perfect, direct, head-on collision paths. Their courses are paired curved pursuit courses, C, Figure 1. By Newton's three laws of motion and Coulomb's law of charges, these paired pursuit courses effectively change most of the initial relative net vector linear momentum of the particles into angular momentum of rotation, R, of the particles of matter. As long as this dipole of matter is not disturbed, it continues to rotate about it's initial axis according to Newton's laws of motion. When this dipole is viewed from the outside, in the plane of rotation, the "plus" and "minus" hemispheres of charge are alternating so rapidly, the dipole of matter "seems" to have no charge when observed in current bubble chambers.
If the above dipole is rotating fast enough for Newton's laws of motion to overcome Coulomb's law of charges, it has a very short life, the dipole separates and the particles are ejected. Otherwise it becomes a stable arrangement of particles of matter. According to Newton's laws of motion, this initial angular momentum is still stored in some manner in most particles of matter. Additional monopoles or other multiparticle combinations can collide with these dipoles to dislodge particles or to form larger groups of particles.
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