Are low-energy photons and gravitons the same thing?

Gravitational waves are like energy ditches that travel across the universe. It’s possible that those gravitational waves form when very low-energy particles travel out from the gravitational center. That raises a question. Does the gravity require a graviton? The extremely low-energy photon can explain gravitation and its strange behavior. 

So, we can think. That maybe graviton is the same thing as low-energy photons. The idea is that a gravitational wave forms when a photon reflects. From the gravitational center. In that process. A photon loses its energy. And maybe. Its energy level can turn so low. That. It starts. To pull quantum fields into it. That causes an idea. That maybe. The mythic graviton. It is a low-energy photon. If a low-energy photon travels across the universe, it binds quantum fields to it. 

That forms an energy ditch, which we can see as a gravitational wave. Another thing that could make those energy ditches is photons that spin very fast. In that case, the fast-spinning photon transports energy out from its edge. And the energy travels to the photon from the larger side. 

But. That explains why gravitational fields turn weaker. When the distance to the gravitational center increases. So, when the number of those with low energy increases in the area. That thing increases the power of the gravity field. And that means that the density of those “special photons”. Or photons that bind energy into themselves increase near the gravity center. 

So the low-energy photon could be the same. As a graviton.

Or at least. It's the particle that is very similar to a photon. The thing that supports the model that the graviton is actually a low-energy photon is that. A gravitational wave travels at the speed of light. The reason why the photon has no mass could be this. The photon pulls energy into it symmetrically. Because. Energy flows to a photon. Are. Symmetrical, which makes the photon flow. There is a possibility that the superstring that travels through a photon pulls energy into itself. But that thing doesn’t matter. 

If we think that gravitational waves are cases where low-energy photons pull quantum fields into them, we could answer the question of how to connect the field model with gravitational waves. When the gravitational center rolls quantum fields around it, that causes an effect. In that case, the fields that travel through photons can form strings. 

Those strings pull energy away from those photons. The idea of this effect is that a photon acts like a ring, and the quantum field is like water that travels through that ring. That quantum field turns photons into a very low energy level. This means that those photons start to pull quantum fields into them. 

"The visual representation of a photon produced by the researchers." (Interesting engineering, Scientists map mysterious shape of photon, could unlock light-matter interaction)

The gravity wave forms when low-energy photons travel out from the gravity center. The reason why black holes send deeper gravity waves is that. It pulls more energy out from those photons than other objects. 

When a particle or some other object falls into the gravity wave. It sends a wave movement ahead of it. The effect is like throwing a stone. Into the water flow. If we throw that stone in the direction where water flows, it forms a fast-moving wave that travels with the water. In the gravitational model, a similar wave that travels ahead of the particle makes a deeper energy ditch ahead of the particle. That energy ditch, shadow, or pothole pulls a particle. Or another object behind it. 

This means that a low-energy photon can act just as the hypothetical graviton. So, could it be possible that the extremely low-energy photon is the same as the graviton? The photon has a lower energy level. Than its environment. That low-energy photon pulls energy. Into it. That means gravitational waves don’t need gravitons. 

The low-energy photons that reflect from the object can explain why the gravitational wave, an energy ditch, can travel across the universe. This thing forms. When extremely low-energy particles are traveling across the quantum fields. And those particles. That could be those low-energy photons bind energy. Inside them. 

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

The Higgs boson collapse and how it ends the universe?

“This abstract illustration depicts a bubble-like multiverse. (Image credit: MARK GARLICK/SCIENCE PHOTO LIBRARY via Getty Images).” (Space.com, The Higgs boson could have kept our universe from collapsing)

There is a theoretical model that the cosmic microvoid can pull a single high-energy photon out from particles like electrons. The Higgs boson collapse means a situation where. The Higgs boson suddenly turns flat like a pancake. That could happen. If the Higgs boson starts to spin so fast that it turns into a flat.  If that happens, energy travels to the edge of that fast-spinning object. The difference between Higgs boson evaporation and Higgs boson collapse is that. The Higgs boson collapse doesn’t release any energy to the environment. 

The Higgs boson still exists. But its shape is turned. If the flat Higgs boson continues its spin, there is a possibility that the particle starts to collect lots of energy into one point. The fast-spinning particle collects energy. Into it. And then energy travels to the edge of that particle. In evaporation. Particle turns into energy. That was stored in it. When the Higgs boson collapses, the quantum fields around it try to fill that point. The fast-spinning boson acts like a thermal pump that transports energy out from that point.

Could that destroy the entire universe? Nobody knows. There is a possibility that the Higgs boson can cause the vacuum decay. There, the universe is filled with cosmic micro- or quantum voids. If a particle gets into a cosmic microvoid, that thing rips the particle into pieces. The reason for that is that the cosmic microvoid increases the speed of energy flow out from the particle. The cosmic microvoid forms. A zero-energy area around the particle. It means it acts a little bit like annihilation. This effect releases free energy into the system. And that can cause. Fatal and global effect on the universe. 

In the cosmological models, the universe began its existence in the Big Bang. There is a limit in the size of the universe. The universe is surrounded by the shockwave. That shockwave. Means. That there must be some kind of quantum field outside the universe. This kind of shockwave causes reflection into the universe. There is a possibility that this shockwave, if it exists, can explain why we cannot see other universes. 

But what happens if that shockwave doesn’t exist? The expansion of the universe would be faster. The reflection from that hypothetical shockwave increases the level of free energy in the system. That free energy causes. The expansion of the universe. This shockwave acts like a vacuum bomb. The reflection travels in the middle of the universe. And then returns to the shockwave. If one of those energy impulses is strong enough, it can push that shockwave out. That releases free energy from particles. This can cause a chain reaction. There, the universe ends its existence. In cosmological models, the geometrical shape of the universe is like a plate or a wheel. 

The fact is that. The single photon can cause a local effect that expands into global form. The energy starts to travel between some of the most common particles. The photon can split in two, and that means the high-energy photon that hits some of the most common particles in the universe can cause resonance between those particles. That harmonic resonation can release so much energy that it rips all particles. Into pieces. The possibility of that is almost zero. But it's possible. That. The so-called cosmic void can pull a photon away from a particle. 

There is a possibility that the Higgs boson collapse turns its environment into a cosmic nanovoid. That nanovoid causes a situation where photons or electrons start to lose energy. I chose those two particles for this text, for example, because they are the most common free particles in the universe. Two things make those particles dangerous. The first one is that they are the most common particles in the universe. The second one is that those particles are so small. That. They send a wave movement, which can hit. 

Straight to the bonds that connect quarks together. If an energy impulse hits those bonds, it travels to the quarks. And then. If that energy kick is strong enough. That releases the energy. That is stored in bonds to space. This process increases energy in the energy wave. 

The chain reaction goes like this. The Higgs boson collapse happens near an electron or photon. That cosmic nanovoid pulls the photon to that point. Then that photon sends an energy wave that hits other photons. This thing causes an effect. In which photons or electrons start to send other photons asymmetrically. When those most common particles start to send photons. Only from another side. 

That thing can cause a chain reaction, where more and more particles start to send energy through the universe. That thing forms a harmonic wave that travels across the universe. That wave can destroy material in two ways. The shockwave can transport so much energy into the atoms that the strong nuclear force cannot keep quarks in the hadrons. The reaction where strong nuclear interaction releases its energy. This releases energy to that shockwave. This thing is theoretically possible if the energy wave can begin its journey through the universe. 

Another way is that an increase in free energy can make a hole. Into that shockwave. Or fast reflection pushes that wave out, which surrounds the universe. This forms the situation. That we can call the quantum pressure decrease. When quantum pressure decreases. That pulls the quantum field around atoms and subatomic components out. That releases energy. That is stored in those particles and the bonds between them. This can cause a chain reaction that can destroy all material. Or it will not destroy the entire material. It rips the hadrons, protons, and neutrons into pieces. 

https://www.livescience.com/higgs-particle-universe-collapse-in-multiverse

https://www.science.org/content/article/tiny-black-holes-could-trigger-collapse-universe-except-they-dont

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

The universe might be a superposition of multiple realities.

"At the deepest level of quantum physics, particles may not be as independent as they appear. New theoretical work shows that nonlocal behavior can emerge simply because identical particles are fundamentally indistinguishable. Credit: Stock" (ScitechDaily, A Fundamental Quantum Rule May Entangle the Entire Universe"

We should stop thinking that some phenomena are local. In quantum mechanics, everything has global interaction. When two particles impact each other, they send waves through the quantum fields. And if we think that impacting photons. Or some other boson's impact. They might not send very high-energy waves. But there are a lot of bosons in the universe. There is a possibility that the photon tunnels through the quantum fields. The idea is that. 

The system puts.  The photon. To spin around its horizontal axle. The photon itself is the donut-shaped particle. And if the hole in the middle of that particle is always in the same direction, that spin movement condenses the quantum field in the middle of that particle. This condensed field turns into a string, and then the photon gets a nose. That. Turns the particle’s shape. Into. A little bit like the Ostankino TV tower. 

The reason for that is that the quantum channel pulls. And stretches particle. The quantum field behind the particle pushes it into that channel. During that process, the nose sends photons. Those photons form the quantum shadow behind it. And that pulls the particle forward. So, how fast does the particle move? Or what’s its top speed? That depends on how long or how fast a particle can move until the energy flow turns away from the particle. 

And that causes an interesting idea. Why. Can a photon travel faster than another photon? The answer is this. When a photon travels in the quantum shadow between two superpositioned and entangled particles. That means a photon travels in a tunnel through those quantum fields. And that tunnel forms a different, separated quantum system. 

That means the photon is in a lower-density quantum system. But can that string form a similar situation? The answer is: if the outside quantum field can press energy into the photon, the photon can accelerate. Until its energy level turns higher. Than its environment. If the quantum field loses its contact with the photon. That particle starts to deliver its energy. So, it's possible that the string that a horizontally spinning photon can form a situation. That energy string travels through the photon and binds energy into it. And that energy travels through the energy ring that surrounds this energy string. We know. That energy donut. As a photon. This string can act like a thermal pump. When it pulls energy through that donut, it keeps quantum fields in contact with a photon. At a higher speed. Than a normal photon. 

“Cherenkov radiation glowing in the core of the Advanced Test Reactor at Idaho National Laboratory” (Wikipedia, Cherenkov radiation)

“Cherenkov radiation is an electromagnetic radiation emitted when a charged particle (such as an electron) passes through a dielectric medium (such as distilled water) at a speed greater than the phase velocity (speed of propagation of a wavefront in a medium) of light in that medium. A classic example of Cherenkov radiation is the characteristic blue glow of an underwater nuclear reactor. Its cause is similar to the cause of a sonic boom, the sharp sound heard when faster-than-sound movement occurs. The phenomenon is named after Soviet physicist Pavel Cherenkov. (Wikipedia, Cherenkov radiation) Things like neutrino detectors use that radiation. When a neutrino arrives in the water, it sends a blue light flash. Which is the same as the sonic boom. 

“The inside of the Compact Muon Solenoid (CMS) experiment at the Large Hadron Collider. Rochester physicists working at the detector have observed spin entanglement between top quarks and top antiquarks persisting at long distances and high speeds. Credit: CERN” (ScitechDaily, Faster Than the Speed of Light: Information Transfer Through “Spooky Action at a Distance” at the Large Hadron Collider)

"A groundbreaking new technique has revealed the first detailed image of an individual photon. (Image credit: Ben Yuen and Angela Demetriadou)". (LiveScience, The shape of light: Scientists reveal image of an individual photon for 1st time ever)

Ostankino tower. 

The density of a quantum system determines the speed of light. 

In a regular way, we think that nothing can travel faster than light. But the fact is something more exciting. The speed of light depends on the environment. The maximum speed of light is 299,792,458 m/s. That is the speed of light in a vacuum. The speed of light is lower in denser spaces. Then we must realize that the speed of light is lower around stars than outside the heliosphere. This means that when a particle enters the solar system, it encounters the impact wave. The speed of light is lower in that impact wave than the speed of the outside impact wave. When a particle impacts at that point, it travels faster than the speed of light. In that moment. The particle must deliver its extra energy to slow its speed. 

To the cosmic speed limit. In the same way. When. A particle impacts Earth's atmosphere. It sends its extra energy as Cherenkov radiation. That means: the reason for. Why.  Earth's sky is blue. It is the same. As the blue shines around nuclear reactors. The blue shine forms when particles that travel faster than the speed of light travel in water and release their extra energy. The particle cannot slow down if it cannot deliver energy into the environment. So, the density of the quantum system determines the speed of light. So. How can we cross that speed limit? The answer is simple. We must just develop a quantum system inside another quantum system. This means that if we create a tunnel. 

There is a vacuum across the water. We can easily transport information faster than the speed of light in water. And if we develop that mode, we can transport information faster than the speed of light. It is in the air. Between superpositioned and entangled particles, information travels through the quantum shadow. That quantum shadow or quantum tornado makes it possible that a particle can travel faster than it travels outside that shadow. In this case, that shadow. Or. Quantum tunneling forms a different quantum system between particles. There is a possibility. To create that kind of tunnel between electrons. And when a photon travels through that tunnel, the quantum maser emission transmits energy into it. The system just puts two electrons into superposition, and then it starts to spin the transmitting electron. When that photon impacts the receiving electron, it delivers its energy to that electron. 

This means that there are no local effects. The Pauli exclusion principle says. That there must not be two identical fermions in the quantum system. The universe is an extremely complicated entirety of systems and subsystems. The Pauli exclusion principle. Determines only the fermion behavior in the quantum system. Things like bosons can go. Into superposition. And the most well-known boson is the photon. Also, there can be identical quantum fields in the system. When we think of that model. The universe is. The network of the superpositioned and entangled particles. The universe is full of identical objects that can turn into a superposition. Black holes are objects that are so dense that they are identical. Except that their size is different. 

https://www.livescience.com/physics-mathematics/quantum-physics/the-shape-of-light-scientists-reveal-image-of-an-individual-photon-for-1st-time-ever

https://scitechdaily.com/a-fundamental-quantum-rule-may-entangle-the-entire-universe/

https://scitechdaily.com/faster-than-the-speed-of-light-information-transfer-through-spooky-action-at-a-distance-at-the-large-hadron-collider/

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

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