Will the Large Hadron Collider test lead to the destruction of the planet?

No, because the speed is not up to that.

There are large ones in the worldParticle Collider: LHC, ILC, BEPC, etc.

The Particle Collider is a device developed on the basis of the Large Particle Collider, the foundation of the high-energy synchrotron.

The main function is to accumulate and accelerate the flow of two particles injected by the pre-accelerator in succession, and make them collide when they reach a certain intensity and energy shed, so as to produce a sufficiently high reaction energy.

Particle collisions, proton collisions, and elemental particle collisions.

The purpose is to test people's experimental instruments and explore the macroscopic effects of microscopic particles, understand the new laws and new particles of quantum particles, and understand the frontier quantum physics such as new physics.

Particle Physical Science. At the same time, particle collision is also a natural particle 'mechanism', and people have explored the causes of 'particle collision mechanism', explored the existence of 'supersymmetry' excess dimension, and developed new materials.

Principle: The particle collider is a device developed on the basis of a high-energy synchrotron, and its main function is to accumulate two streams of particles injected by the pre-accelerator in succession with a certain beam intensity and a certain energy, so as to produce a high enough interaction reaction rate for easy measurement.

Quantum mechanics and related scientific phenomena in the microscopic world.

Particle collision helps us to study the universe, the tiny particles in the universe collide, and then produce, the small between multiple particles, the cumulative words are large, and the large number of debris produced by the large is of great help to the study of the mysteries of the universe, and the study of particle collisions is very propulsive to the study of the mysteries of the universe. <>

It has been more than ten years since the invention of the particle collider, and the results have been achieved, especially the discovery of the Higgs boson, the Higgs boson is: the boson predicted by particle physics with zero spin, the last undiscovered particle in the Standard Model, and the Higgs boson helps scientists understand the reason why other particles have mass.

With the development of science and technology, China has built a better machine than the particle collider to become the annular positron collider (CEPC), which will lead China to the forefront of the world's science and technology. The Particle Collider is a ring-shaped machine, tens to hundreds of kilometers long, that accelerates particles to nearly the speed of light and collides. <>

Physicists believe that the particle collider will help mankind explore the mysteries of the universe, but also there is a risk, if the experiment fails, the particles collide and cause the consequences of space tearing, and even produce a black hole, the earth may be produced by the particle collider to encounter an unprecedented disaster, may compress the earth into a singularity like a black hole.

In the face of doubts, the ONU is clear: black holes produced by particle collisions are all small black holes, which will not disintegrate for a long time and will not endanger the earth. The particle collider evaluation team said it was safe, and that before the artificial particle collision, there were also small-scale particle collisions in nature, which did not endanger the earth.

Physicist Stephen Hawking said that particle collisions in the atmosphere are a frequent occurrence, but the Earth has always been immune to the impact.

I firmly believe that particle collisions will not have a negative impact on the earth, but I hope to take precautions to ensure the safety of the earth.

Liquid helium is constantly flowing in complex pipes inside and outside the Large Hadron Collider (LHC), and thanks to this cryogenic cooling system, it is even colder than interstellar space. So why does it need to stay so cold? Serge Claudet, head of the cryogenic team at CERN, said magnets can't work without keeping them cold.

<> winding cable allows the LHC's powerful electromagnet to carry 11,800 amperes, roughly equivalent to a small lightning bolt. For a finger-wide cable to carry such a large current without burning out, it must be a superconductor. A superconductor is a conductor of electric current with zero resistance.

Every time you turn on the light, you can see that there is resistance. If the filament of a bulb is made of superconducting wire, it neither generates heat nor emits light, and electricity flows directly through it.

Most industrial superconductors can only acquire the magical properties of superconductivity at low temperatures above absolute zero (Celsius) in the early position. The Large Hadron Collider is located in a fairly warm tunnel, about 27 degrees Celsius. To protect the superconducting magnets from this mild climate, the engineers protected the core with multiple layers of insulation, each colder than the next, like a nested Russian doll.

The Large Hadron Collider (LHC) is one of the coldest places on Earth. Its main magnet operates at temperatures that are even lower than those of outer space. To bring the LHC to this temperature, 120 tons of liquid helium flow through a closed loop in the veins of the accelerator.

The LHC's cooling system consists of cryogenic islands of eight helium coolers. Each even-numbered point and 8 point on the accelerator has two chillers, one from the LEP era and the other from a newer chiller from the LHC start-up period. The paraffin freezer consists of two boxes, one on the cold side of the tunnel and the other downstream of the tunnel, which produces superfluid helium from 20K (and 20K of cold helium at room temperature) - a device located inside the cave at a temperature that produces superfluid helium.

Because the liquid gas is constantly flowing in the complex pipes inside the Large Hadron Collider, because the cryogenic system is colder than interstellar space, just like the matryoshka dolls, each layer is colder than the next, most industrial conductors can only obtain ultra-small magical special characteristics at sub-zero, in order to make the superconducting heart body not affected by this mild gas leakage, so the Large Collider is one of the coldest places on Earth, in order to reach this temperature, 120 tons of liquid gas flow through a closed loop in the vein.

Because the temperature generated in this collider is very low-profile, it can even reach absolute 0 degrees, and there is no way for people to survive in the dust cover, so it is the coldest place in the world.

Because this place has a lot of liquid nitrogen, and only if the temperature is low enough can there be such a thing, so there is such a saying.

The Hadron Collider can't really create a black hole.

According to the nature of gravity described by Einstein's theory of relativity, it is impossible to create a tiny black hole inside the Large Hadron Collider. However, some pure theories predict that the Large Hadron Collider will produce this particle product. All of these theories suggest that such particles from the Large Hadron Collider will decompose immediately.

As a result, the black hole it creates will have no time to concentrate the matter and produce visible results.

Unlike the collision of celestial bodies such as the Earth and cosmic rays, the new particles produced during the collision in the LHC generally travel more slowly than the particles produced by cosmic rays. Stable black holes are either charged or neutral.

Whether it's particles produced by cosmic rays or particles produced by the Large Hadron Collider, if they are charged, they can bind to ordinary matter, and the process stops as the particles travel through the Earth. The fact that the Earth still exists precludes the possibility that cosmic rays or the Large Hadron Collider could create tiny black holes that are charged and dangerous.

Hehe, artificial black holes.

The European Large Hadron Collider (LHC) is known as the world's largest scientific project, which will use the huge energy generated by the collision of high-speed particle beams to reconstruct the cosmic shape after the "big **" occurs. Opponents in Europe and the United States, however, have filed separate lawsuits in local courts to halt or postpone the project, arguing that the LHC could produce dangerous particles or miniature black holes that could destroy the entire planet.

According to Professor Lesler's estimates, there is a high probability that the LHC will produce a miniature black hole in the experiment, which will expand exponentially and devour the Earth from the inside out, with the worst-case scenario disappearing within 4 years.

But CERN scientists released a safety report for the LHC program earlier this year, which was endorsed by an external panel of experts. The report states that the theoretical possibility of a miniature black hole in the collider is slim to none. Collisions of much higher energy than LHC are also frequent in nature, and cosmic ray particles coming at close to the speed of light often collide on the surface of the Earth, but the Earth is not swallowed by any greedy black hole.

These miniature black holes aren't just tiny black holes, they're actually subatomic in size, about the size of an electron or a proton. If the Large Hadron Collider were to operate for a hundred years, all the energy produced by these particles would not even be enough to light an electric lamp. Although the LHC produces trillions of electron volts, the maximum rate at which the LHC produces a tiny black hole is likely to be one per second, and such a small rate simply cannot cause perceived harm to anyone.

These miniature black holes are unstable, and they collapse quickly. In fact, these black holes are going in the opposite direction, spewing out radioactive material, so they will eventually disappear without a trace, instead of constantly devouring matter, getting bigger and bigger, and finally eating the Earth.

According to Werner Heisenberg's "uncertainty principle", there is some slight possibility of anything happening, but the probability of this happening is very small, and it may not happen in the lifetime of the universe.

If the particle collider fails, will a black hole really be born? Scientists give the answer.