Who knew that electricity came in two flavors? Well, Tesla seemed to know and so did Edward Leedskalnin. A lot of people drop theses names when physics seems to be twisted. Yet, another name that needs to be included here with these two is Jean Charles Athanase Peltier.
The Peltier Module is a device that uses both exothermic and endothermic properties. It gets hot on one side and cold on the other when it’s in operation. This device can be found as close as the bottled drinking water dispenser that serves hot and cold water. Who knew that a technology that could power the world is as close as the water cooler?
Yes, electricity comes in two flavors. One flavor compresses electrons through the circuit the other pulls electrons through the circuit. When electrons are compresses they get hot. Like wise pulling electrons cools them off. We see the same phenomena with Freon in a conventional refrigeration system. Compressing the gas’s electrons emits photons or heat. Decompressing the gas’s electrons absorbs photons or cools.
So, how dose this all work? Well, both are lethal if you ignore a few rules. The trick here is knowing to flip the rule set for endothermic electricity. It works backwards of exothermic power as it doesn't need a complete circuit to operate. Resistance, or an open ground, is needed to stabilize such a circuit. In fact it’s more dangerous to work with a closed circuit.
Coils act as oscillators when exposed to direct endothermic current. As power flows through the coil it cools increasing the magnetic field strength generated. Eventually the magnetic field becomes so strong as to stop the electron flow until it warms some causing it to oscillate. A short in an endothermic system will freeze and lock the generator causing it to fly into pieces (conservation of momentum). In perpetuity, endothermic power works well with electrostatic motors and circuits because of their higher resistance.
Atoms and permanent magnets seem to be perpetual or have complete loops. As it turns out neither endothermic or exothermic power in itself is a complete loop. However, if you feed both into a circuit pushing and pulling electrons simultaneously it starts to resemble a similar complete loop. In this event conventional electromagnetic motors run at full speed even loaded. Velocity being constant, what differs is the torque the motor can produce as the power is turned up. However, once the torque threshold has been overcome the motor stops or breaks (beware of the conservation of momentum again).
How is it that the motor’s torque is affected and not it’s velocity? It comes down to molecular friction or heating. Cooling a magnet makes it stronger. Heating a magnet makes it weaker. With both endothermic and exothermic power running through an electromagnetic motor a balance is created. Loading the motor sways the balance toward the endothermic side increasing the magnetic field density. Unloading the motor sways the balance toward the exothermic side decreasing the magnetic field strength. The motor’s torque output is directly linked to the fluctuating magnetic field.
The motor’s velocity is set or controlled by the ratio of endothermic verses exothermic power that is applied to the unloaded motor. If the balance favors endothermic the motor runs faster. If the balance favors the exothermic the motor runs slower. This is all in regard to the overall electric field applied.
The best part of mixing the two is if you find yourself between the power and ground of a balanced system, the net electron transfer causes no heating or cooling and no cellular damage at any voltage. Now, there’s a lot I don’t know dealing with frequencies and the combination of the two flavors. But, I would wager that the equation for gravitational field strength resembles the equation for electrical field strength more closely than we know. Currently there is no negative gravity side of the equation. However, I wonder if that will change as the endothermic equations are added to the mix.