Background Knowledge |
To understand our products, one must know a little about quantum mechanics:
Quantum mechanics is the study of subatomic particles, some of which are made of even smaller particles. For example, the protons and neutrons that form the nuclei of atoms are made of tiny charged particles called quarks, along with other things, such as gluons. Quantum entanglement is the branch of quantum mechanics we are applying to our solution for the lack of renewable energy.
A subcategory of quantum mechanics, quantum entanglement, describes a phenomenon in which two or more particles are linked. All of the entangled particles’ quantum states rely upon the others. If one of them gains energy, the others do too. The same goes for losing energy. For more information about quantum physics, read this ARTICLE from How Stuff Works. At a minimum, scroll down to the entanglement section to understand this phenomenon. Having two particles that share changes in states is crucial for our energy solution.
Quantum mechanics is the study of subatomic particles, some of which are made of even smaller particles. For example, the protons and neutrons that form the nuclei of atoms are made of tiny charged particles called quarks, along with other things, such as gluons. Quantum entanglement is the branch of quantum mechanics we are applying to our solution for the lack of renewable energy.
A subcategory of quantum mechanics, quantum entanglement, describes a phenomenon in which two or more particles are linked. All of the entangled particles’ quantum states rely upon the others. If one of them gains energy, the others do too. The same goes for losing energy. For more information about quantum physics, read this ARTICLE from How Stuff Works. At a minimum, scroll down to the entanglement section to understand this phenomenon. Having two particles that share changes in states is crucial for our energy solution.
How our batteries work
The way we use quantum entanglement is by entangling particles in two batteries (it is possible to manually entangle particles). This concept was first hypothesized back in the early 20-teens. Here is an early Article discussing the possibility of entangling particles in a pair of batteries. However, this forward thinker missed the amazing part of entangling batteries. Entangled particles are not bound by location. Like early speculation, we confirmed that entangled particles will share states regardless of distance.
Our ConstantChargeTM battery solution uses entanglement to create a state of constant charging. Battery A is in a state of constant charging, housed on a solar charging satellite. Battery B is used to power a motor (or any other electrical application). Since these two batteries are entangled at the quantum level, the charge level is the same on both batteries. The last step of the puzzle is creating a battery array that provides the level of electricity you need. Using this method, battery B will always have power. Better yet, once deployed there is virtually no cost associated with solar charging.
Our ConstantChargeTM battery solution uses entanglement to create a state of constant charging. Battery A is in a state of constant charging, housed on a solar charging satellite. Battery B is used to power a motor (or any other electrical application). Since these two batteries are entangled at the quantum level, the charge level is the same on both batteries. The last step of the puzzle is creating a battery array that provides the level of electricity you need. Using this method, battery B will always have power. Better yet, once deployed there is virtually no cost associated with solar charging.
ConstantChargeTM in action
Our ConstantChargeTM solution was first used in deep space exploration. Battery A was being charged constantly and battery B was used to power a space craft. This solution allowed space craft to have a constant level of power regardless of location in the universe.
This solution is able to provide infinite energy to power a spacecraft, allowing it to travel much farther than ever before. Space exploration missions can reach far beyond the solar system, and even travel to other solar systems. Crafts using this power source can literally travel an infinite distance without ever having to refuel.
This solution is able to provide infinite energy to power a spacecraft, allowing it to travel much farther than ever before. Space exploration missions can reach far beyond the solar system, and even travel to other solar systems. Crafts using this power source can literally travel an infinite distance without ever having to refuel.
Why charge these batteries in space
A solar array in space is essential to our solution. In space, solar panels produce several times the electricity they do on earth because the earth’s atmosphere filters out a lot of sunlight. In addition, who wants enough solar panels to power a spaceship in their backyard.
Our solar panels use electromagnetic radiation to produce electricity. Like most panels, they only use the visible spectrum of radiation (wavelengths of 380 nm to 750 nm). 55-60% of this radiation would be reflected back into space or absorbed by earth’s atmosphere, so that means our competitors solar panels on earth can only generate 40-45% of what ours can in space. Solar power amounted to a very small percentage of electricity generation in the 20-Teens (only 0.4% of total energy production in the U.S.). It was underused source mainly because of its low cost efficiency, but we changed all of that. Today solar accounts for 94% of total energy consumed (some people have not converted their classic cars over).
Our solar panels use electromagnetic radiation to produce electricity. Like most panels, they only use the visible spectrum of radiation (wavelengths of 380 nm to 750 nm). 55-60% of this radiation would be reflected back into space or absorbed by earth’s atmosphere, so that means our competitors solar panels on earth can only generate 40-45% of what ours can in space. Solar power amounted to a very small percentage of electricity generation in the 20-Teens (only 0.4% of total energy production in the U.S.). It was underused source mainly because of its low cost efficiency, but we changed all of that. Today solar accounts for 94% of total energy consumed (some people have not converted their classic cars over).
Our AbsoluteZeroTM Motors
To minimize the charging required and battery weight, we created a 100% efficient motor to power your craft. This motor uses superconductors to create this efficiency. A superconductor is a conductor that has no friction, and therefore has no energy lost to heat. This causes the conductor to be 100% efficient. A superconductor uses very cold temperatures (-234 C) to eliminate energy loss. This was not practical on earth because it took a lot of energy to get to the superconductor. However, using our space cooled design, we were able to make our motors superconducting with virtually no energy. Since space can reach low temperatures of around 2.7 Kelvin (-270 Celsius, -455 Fahrenheit), this temperature is low enough to cool a superconductor, which requires around 39 Kelvin (-234 Celsius, -389 Fahrenheit) to be 100% efficient.