By manipulating light, researchers can create futuristic quantum computers and stealth systems. But it can make a revolution in energy production.

What would you do with two identical light beams? That thing makes it possible to create the ultimate error correction for quantum computers. Things like photon snakes can use as photonic tape stations that can transport information with new efficiency. Light can push objects, and photon-accelerated electrons can be the next-generation systems for civil and military sectors. Photons can push electrons and protons in the beam lasers. 

If ion cannon shoots two internal particle beams with positive and negative particles the electromagnetic pulling effect keeps that beam in form. Lasers or photon clouds can also input energy to electrons and positrons that travel in the particle accelerators. If the system can create high energy stopped or standing photons, that thing makes fundamental things in the R&D work in quantum and nanoscale systems. 

In quantum networks, the system drives information in the frame where the trapped photon is. Then that frame sends information into that photon. Then the system puts that photon will into superposition and entangled it with other photons. Because the energy level in the framed photon is higher than the receiver information travels in the quantum network. If the quantum network can operate by using two identical information channels. The system can detect errors with very high accuracy. That requires the ability to create two identical light beams. 

One way to manipulate light is to slow down photon speed. Normally, that happens in the medium, but the medium pulls energy from photons. And that makes it hard to use that effect in quantum computers. When a photon loses its energy, that affects the information stored in it.

"Entangled quantum objects can be used to network separated systems. The researchers demonstrate what is needed for nonlocal correlations, a requirement for a useful quantum network. Credit: The Grainger College of Engineering at the University of Illinois Urbana-Champaign/Wesley Moore" (ScitechDaily.com/Decoding Quantum Nonlocality: A New Criterion for Quantum Networks)

But otherwise, slowing photons gives the system more time to read that information. The best possible way to manipulate light and slow the photon is to use gravitation. The problem is how to make the synthetic gravitational effect that pulls a photon behind its source.

This is one reason why antigravity at the quantum level is so interesting. Gravitation affects all particles in the same way. And that thing makes it so-called cold energy. Because the energy level in a photon doesn't change with gravitational slowing, it can protect the photon's internal superpositions. But when we think that light manipulation at the quantum level is the ultimate tool, we can also use that thing without antigravitation.

The ability to create single photons will make fundamental computer solutions possible. The intelligent helmet that involves a quantum computer, in which qubits are smaller than atoms, can be the next-generation version of the portable quantum computer.

The photons can drive information to electrons and other particles. In those versions, the photons can store information in certain areas of the electron's shell. Or the same single photon can load information into quarks inside protons and neutrons. That thing makes it possible to create extremely small quantum computers by using quantum entanglement between quarks. That kind of quantum computer that is smaller than an atom can be installed in intelligent helmets. And it can communicate directly with the brain. That thing would be the most fundamental BCI system that we could ever imagine.

But manipulating light involves much more than just quantum computers. Quantum entanglement makes it possible to create layers that drive photons in one direction. That kind of system makes objects invisible. There is a possibility that by using electrons trapped in graphene If those electrons are stressed with precisely the right type of energy stress, they could create phonons that have the same energy level as impacting photons.

That thing forms a standing light wave between the object and incoming light. If there is a lower energy area behind that standing light wave, that makes it possible for the information to travel only in one direction. This kind of system requires superconductor technology. But new superconductors, along with advanced AI and powerful computing, make those systems real.

Standing light waves can also revolutionize things like photovoltaic cells. The system would trap light above the solar panels. Then the system can drive light into the photovoltaic cell from that standing light wave. But those things are the systems of tomorrow. The fact is that. New types of superconducting technology and other things like ultra-sensitive perovskite-based photovoltaic cells are making these kinds of systems closer than we even imagine.

https://bigthink.com/the-future/discoveries-about-light/

https://scitechdaily.com/quantum-breakthrough-light-source-produces-two-entangled-light-beams/

https://en.wikipedia.org/wiki/Quantum_nonlocality