What does it mean for two waves from separate point particles to touch and rub each other? Consider a point particle again as a ball of yarn. A ball of yarn is made up of string that has a static tendency when rubbed. Let us say that you loosened the ends of two balls of string (the ends that were on the outside). You rubbed these ends against each other briefly. What happened? The fray of the strings interconnected to an extent (depending on the toutness of each string), the strings became slightly charged one toward another, and a slight amount of heat was produced. Now, what if you rubbed these string ends for just a little bit longer and then let go? What would probably happen? The strings would stay together for at least one moment. Why? When the strings’ ends are rubbed, an electrostatic discharge happens to a slight extent between these ends. Electrons rub around, giving off a mild charge. The mild charge is in terms of the angular momentum that is dispensed during the rubbing of the described electrons, while the shock of voltage that one could potentially receive from this is due to the spin-orbital interaction of the described electrons. The described angular momentum is in terms of the roll of the electrons as a transversal radiation. The propagation of this energy is the electric filed in this case. In order for there to be roll, there has to be spin and orbit. As the electrons roll around between the ends of the metaphorical yarns of string, these are also spinning (twisting 90 degrees to the twist that happens during the roll) and orbiting each other (moving radially as a whole relative to each other). The propagation of the energy given off as the result of this spin and orbit type motion is the magnetic field dispensed here. From experience, when you spin a bunch of materials near each other, what happens? The materials get sucked into each other! So, when there is a magnetic discharge between two objects, what tends to happen? The two objects tend to be brought in toward each other! I will continue with the suspense of this session later.
Until then, you have a phenomenal day! Sam
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