Skip to main content

Black holes are the brightest objects in the universe.


"This artist’s impression shows the record-breaking quasar J059-4351, the bright core of a distant galaxy that is powered by a supermassive black hole. Using ESO’s Very Large Telescope (VLT) in Chile, this quasar has been found to be the most luminous object known in the Universe to date. The supermassive black hole, seen here pulling in surrounding matter, has a mass 17 billion times that of the Sun and is growing in mass by the equivalent of another Sun per day, making it the fastest-growing black hole ever known. Credit: ESO/M. Kornmesser" (ScitechDaily, Brightest Object in the Universe Discovered – Powered by Supermassive Black Hole Eating a Sun a Day)


The brightest object in the universe eats a sun in a day. That supermassive black hole is in quasar J059-4351. The paradox is that the black holes are the brightest objects in the universe. The paradox is that the black hole itself will not send any radiation, but its transition or material disks are very bright. 


The Sagittarius A* gives new data about the time dilation and speed of light.


Supermassive black holes are the most powerful objects in the universe. Things like rotation speed or spin is the thing that makes supermassive black holes interesting. The spin of the Sagittarius A*, or Sgr A* is about 60% of the speed of light. When material falls into the supermassive black hole, it forms a transition disk, the spiral structure around the mass center. The spiral continues behind the event horizon, or the point. Where escaping velocity crosses the speed of light. 

That means inside the event horizon photon and other particles travel with the same speed. The speed of photons is higher than other photons because the massive gravity effect pulls it from the front side. When a particle closes the black hole, massive gravity starts to pull it into a form that looks like spaghetti. This effect will turn things like quarks into elongated things. 

When we think that black holes are like potholes, that gravitational pothole turns the universe smaller. The reason for that effect is this black hole collects more information into that pothole. There is no reflection because all photons and other material and wave movement travel into the black holes. And the last particle that can escape from the massive gravity is the photon. 

Black holes also prevent the Hall fields or potential walls from forming because they pull all energy inside it. Some electrons and photons whirl around the event horizon. Those whirling particles get their energy from the material disk, which sends radiation also inside the black hole. That raises those particle's energy levels to extremely high. 


"This artist’s illustration shows a cross-section of the supermassive black hole and surrounding material in the center of our galaxy. The black sphere in the center represents the event horizon of the black hole, the point of no return from which nothing, not even light, can escape. Looking at the spinning black hole from the side, as depicted in this illustration, the surrounding spacetime is shaped like an American football. The yellow-orange material to either side represents gas swirling around the black hole. This material inevitably plunges towards the black hole and crosses the event horizon once it falls inside the football shape. The area inside the football shape but outside the event horizon is therefore depicted as a cavity. The blue blobs show jets firing away from the poles of the spinning black hole. Credit: NASA/CXC/M.Weiss" (ScitechDaily, Warp Speed Ahead: How Our Galaxy’s Black Hole Bends Spacetime)

One reason for high-power gamma- and X-ray impulses is in the relativistic jet. When particles at the edge of a relativistic jet and the jet's energy fields interact with gas around the black hole, that effect forms intensive high-energy radiation. The radiation forms when energy from those particles and energy fields transfers into the material disk. When particles hit that material cloud they deliver energy. And that energy transfer is the thing, that forms gamma- and X-rays. 

The weight of the Sgr A* is over four million suns. Accurately its mass is 4,30 million suns. Still, that thing is like a rugby ball. There is the possibility that the relativistic jet pulls the Sgr A*'s energy fields with it. And that forms a cosmic vacuum that stretches the black hole. Or some kind of energy tunnel travels through the black hole. In the third model, the fast spin curves the gravity fields, and that causes the rugby-ball-shaped structure. That means gravity in its poles is a little bit weaker than in other points in it. 




There is suspicion that hypothetical Hawking's radiation forms when those photons in hyper-high energy levels make a superposition. The requirement for that is this: the other electron or photon is in a different energy level. And they oscillate with the same frequency. The idea is that the lower photon (or electron if that thing is an electron pair) has a lower energy level because a black hole pulls energy out from it. 

At the point of the event horizon, gravitational waves can also orbit the black hole. Standing gravitational waves can transport energy into the particles or other wave movements that travel through the event horizon. So Hawking radiation can come from the energy bridges between superpositioned and entangled particles. And because the radiation comes from the end of those energy bridges its wavelength is very small and wave rise is not very high.  

The standing gravitational waves that harvest energy from their environment can turn very high energy levels. In that model, gravitational waves interact like all other wave movements. That means higher energy gravitational waves transport energy to the lower energy gravitational waves. And they also can push those gravitational waves away. That thing can explain why black holes send wave movement. 

When those superpositioned particles touch the event horizon their energy positions change places suddenly. The lower energy particle turns suddenly into a higher energy participant of the quantum entanglement. That thing sends an energy impulse to the upper particle. So that means Hawking radiation can come from that kind of photon pairs or energy bridges between them. 


It's possible. That event horizon can transport energy into the energy bridge that travels between superpositioned and entangled particles. 


When those superpositioned particles fall into the black hole through the event horizon the energy level of the lower photon turns suddenly higher, and that sends an impulse through the energy bridge when that thing travels through the event horizon. In that model, the other photon pumps energy to the photon that was in a higher energy level just before the lower photon touches the event horizon. 

A black hole's speed cannot cross the speed of light if we look at the things outside the event horizon. But as we know speed is also energy. The thing is that the virtual crossing at the speed of light is possible. In that case, the outside energy that impacts the particle along with the kinetic energy can raise its energy level to a level that is higher than the speed of light causes. 

Kinetic energy is wave movement that the particle traps. When a particle travels in the universe, quantum fields touch it like plaque. That plaque is the kinetic energy. The reason why particles cannot cross the speed of light is that in the critical moment, the energy jumps away from the particle and starts to travel to the environment. This thing denies crossing the cosmic speed limit. 

But virtually crossing the speed of light is a very easy thing. At the quantum level. Speed is similar to in our size world. That means the same rules that affect vehicles like cars can used for modeling speed and impacts of subatomic particles. 

The thing is that when two particles like electrons impact with speed of 60% of the speed of light, the impact speed is 120% of the speed of light. In that case, a high energy level causes virtual crossing at the speed of light. In the same way, objects can hit denser energy fields at extremely high speeds. And that thing could load more energy into it than it normally does. 

The reason why anything that has mass cannot cross the speed of light can be the same as the thing. That nothing that has no mass, cannot have unlimited slowing speed. When particles like electrons travel in a vacuum and then suddenly hit the water they take that impact into their quantum field. The electron's internal structure jumps forward and that movement in the quantum field causes photon's formation. 

One down quark and two up quarks form the proton. In neutron, there are two down and one up quark. Those quarks form a structure, that looks like a trapeze. In that structure, one quark hangs between two quarks. In a proton, two up quarks hang one down quark. When a proton or neutron hits water with its maximum speed one quark jumps forward and starts to rotate around those structures. 

That rotation movement is like a bolt that we can rotate between our hands keeping the wire from both ends. That movement pumps energy out from the proton. When a particle moves energy into its environment. It must form a photon. And then that photon transports energy out from that particle. That is the thing, that we see as Cherenkov radiation. 


https://scitechdaily.com/brightest-object-in-the-universe-discovered-powered-by-supermassive-black-hole-eating-a-sun-a-day/


https://scitechdaily.com/warp-speed-ahead-how-our-galaxys-black-hole-bends-spacetime/


https://learningmachines9.wordpress.com/2024/02/21/black-holes-are-the-brightest-objects-in-the-universe/


Comments

Popular posts from this blog

Quantum breakthrough: stable quantum entanglement at room temperature.

"Researchers have achieved quantum coherence at room temperature by embedding a light-absorbing chromophore within a metal-organic framework. This breakthrough, facilitating the maintenance of a quantum system’s state without external interference, marks a significant advancement for quantum computing and sensing technologies". (ScitechDaily, Quantum Computing Breakthrough: Stable Qubits at Room Temperature) Japanese researchers created stable quantum entanglement at room temperature. The system used a light-absorbing chromophore along with a metal-organic framework. This thing is a great breakthrough in quantum technology. The room-temperature quantum computers are the new things, that make the next revolution in quantum computing. This technology may come to markets sooner than we even think. The quantum computer is the tool, that requires advanced operating- and support systems.  When the support system sees that the quantum entanglement starts to reach energy stability. I

The anomalies in gravity might cause dark energy.

"Physicists at UC Berkeley immobilized small clusters of cesium atoms (pink blobs) in a vertical vacuum chamber, then split each atom into a quantum state in which half of the atom was closer to a tungsten weight (shiny cylinder) than the other half (split spheres below the tungsten). (ScitechDaily, Beyond Gravity: UC Berkeley’s Quantum Leap in Dark Energy Research) By measuring the phase difference between the two halves of the atomic wave function, they were able to calculate the difference in the gravitational attraction between the two parts of the atom, which matched what is expected from Newtonian gravity. Credit: Cristian Panda/UC Berkeley" (ScitechDaily, Beyond Gravity: UC Berkeley’s Quantum Leap in Dark Energy Research) Researchers at Berkeley University created a model that can explain the missing energy of the universe. The idea is that the particles and their quantum fields are whisk-looking structures. Those structures form the superstrings that are extremely thi

Neon and time crystals can be the new tools for quantum computing.

"New research investigates the electron-on-solid-neon qubit, revealing that small bumps on solid neon surfaces create stable quantum states, enabling precise manipulation. This research, supported by multiple foundations, emphasizes the importance of optimizing qubit fabrication, moving us closer to practical quantum computing solutions." (ScitechDaily, Quantum Riddle Solved? How Solid Neon Qubits Could Change Computing Forever) Researchers created a superposition in solid neon. And those neon ions, where the system creates superposition in their surfaces.  Making it possible to manipulate those atoms. The atom-based qubit has one problem. Orbiting electrons cause turbulence in their quantum fields. The thing that can solve the problem is to use the quantum fields for the superposition.  If the system can position electrons at a certain point, it can make a small hill to the atom's surface. And the system can use that thing for making quantum superposition between the mos