Michio Kaku announced that something strange happened after turning on the Large Hadron Collider

 


Legendary Scientist SHATTERS THE SILENCE and Makes Something AMAZING Regarding UFOs and CERN.

The Large Hadron Collider (LHC) in Geneva, Switzerland, has been the most unprecedented scientific achievement since it was opened on September 10, 2008. It was built by CERN, and its colossal particle accelerator has enabled scientists to probe the world beneath the atom and examine theories like the Big Bang.  But nothing is guaranteed and successful; recent comments by well-known physicist Michio Kaku have introduced odd findings and even possible dangers surrounding the LHC.

What is the Large Hadron Collider?



The LHC is the largest and most powerful particle accelerator in the world. It is a ring-shaped tunnel of 27 km circumference, located 150 metres underground, which consumes approximately 200 million watts of electricity, the same amount as a small city.

How does it function?

Proton acceleration: Employ 10,000 1.9 Kelvin (close to absolute zero ) cooled magnets to accelerate protons close to the velocity of light .

High-energy collisions: Saturate protons with up to 13 teraelectronvolts of energy, more than a supersonic jet crash force .

Goal: To disintegrate protons into subatomic particles to simulate conditions akin to the early universe, shortly following the Big Bang .

Major Discoveries

1. The Quark-Gluon Plasma

The ALICE project at CERN tried to recreate the quark-gluon plasma, a form of matter that formed microseconds after the Big Bang.

Method: Make lead nuclei, each with over 200 hadrons, collide.

Result: Achieved plasma synthesis, even though it wasn't possible to reproduce the sweeping phenomenon of the Big Bang.

Risk: This material, which occurs in neutron stars, can theoretically trigger immense explosions under harsh conditions.

2. The Higgs Boson: The God Particle

The LHC proved the existence of the Higgs boson, an elementary particle crucial in the theory of the Big Bang, in 2012 .

Role of the Higgs Boson: It gives mass to elementary particles via the Higgs field .

Effect: Without this particle, the universe would never have developed as we experience it.

Potential Risk: The great energy of the boson might, theoretically, initiate unstable reactions, such as massive explosions.

3. New Particles: Pentaquark and Tetraquarks

In 2022, the LHC unveiled the discovery of:

Pentaquark: A five-quark particle, four ordinary and one antiquark.

Tetraquarks: For the first time ever, two-particle pairs consisting of four quarks each were seen.

These results leave the way open for a greater understanding of particle physics and imply that there are countless particles that remain to be discovered.

Possible Dangers: Should We Fear Them?

1. Quantum Black Holes

Astrophysicist Martin Rees warned that high-energy collisions may produce quantum black holes at the LHC.

Probability: While CERN has dismissed this theory, there is no definitive proof to preclude the formation of these tiny black holes.

Effect: They might emit strong radiation or even induce unexplained phenomena in the space-time continuum .

2. Mandela Effect: Parallel Universes

Mandela Effect is the shared false memories of past events.

Example: Most individuals falsely recall Nelson Mandela having died in prison instead of becoming president of South Africa in 1994 .

LHC Theory: There are some who think that LHC collisions might have changed reality or opened up portals to parallel universes.

3. Danger of Global Catastrophic Explosions

Michio Kaku has cautioned that if there is an unintentional release of a lot of energy, the LHC has the potential to cause a Big Bang- style inflation event with catastrophic effects for the world.

The Future: The New Hadron Collider

A new hadron collider by the name of the Future Circular Collider is set to be constructed by CERN and could:

With a circumference of 100 km, it is nearly four times the LHC size.

Reach collision energies of 100 teraelectronvolts, opening the door to new discoveries.

Cost estimate: $22 billion, with potential for completion by 2050.

This project might enable scientists to:

Investigating dark matter and dark energy.

Testing more sophisticated theories, including the theory of inflation and parallel universes.

Conclusion

The Large Hadron Collider has opened a huge new understanding of the universe and subatomic particles. Still, recent remarks by Michio Kaku and other experts bring to mind the fact that science tends to step into untested and even harmful areas.

As CERN pushes on with its experiments and gears up to construct a new, even larger collider, the controversy surrounding the dangers and benefits of such work is far from resolved. Are we on the brink of revolutionary scientific breakthroughs or are we recklessly inviting disaster?

Time, and possibly the next hadron collider, will tell.

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