Most of the magnets that are being used to generate electricity are called ‘quantum’ magnets because of their ability to carry electrons much faster than the rest of the magnetic system. A quantum magnet is essentially a tiny, superconductive material that can be used to store and transfer lots of electric charge very quickly. Some quantum magnets can store up to 1,000 times as much energy as the magnetic field, allowing one quantum magnet to store hundreds of kilowatts of stored electricity. However, the current state-of-the-art of quantum magnetics is still at the low-temperature level. At the same time, as we have described above, quantum magnets can be made much larger and very large, depending on the number of electrons that can be stored.
What does a ‘quantum computer’ really do?
A quantum computer is basically a device that can encode information in a way that is never repeated, just like the DNA double helix, but the data is stored in a different form. Currently, two different types of quantum computers have been built – the so-called ‘cascade’ and the ‘qubit’. The cascade computer can store information in a way not only that has never been done before, but also using the same amount of power as a conventional computer. The qubit is very similar to a conventional computer, but instead of storing bits, it can record information and write down the numbers in a way that will always be repeated. Although it is not very different from a conventional PC, it is much smaller and uses much less energy.
How can an electricity generation facility be used to generate power?
As we have seen, a quantum or ‘quantum cascade’ or ‘quantum computer’ is the next step. This could generate electricity with no other source! The quantum cascade can be considered as a miniaturised version of a solar PV panel. This means that it can be used to generate electricity at home, anywhere where electricity is available. Quantum computing will be especially useful because it can greatly increase the number of people that can be powered, providing a much smaller footprint and making large ‘distributed’ installations possible.
What happens when you combine quantum computing and nuclear power?
It all depends on when the next generation ‘quantum computers’ are implemented into nuclear power plants. Currently, the biggest use cases for nuclear power include producing electricity from waste heat. The problem is that nuclear waste contains large numbers of highly radioactive materials so to extract the electricity the
free energy diagram, free energy definition thermodynamics meaning, free energy generator 100% self running simple ideas to make money, free energy devices youtube, karl friston’s free energy principle