Higgs Boson, And Can It Destroy Our Universe?

Several scientists have suggested that new laws of physics or particles that have not yet been discovered could protect the entire universe from the dangers posed by the Higgs boson. The dilemma was resolved decades ago, but it remains to be seen whether mathematics explains reality.

In the 1960s, physicists including François Englert and Peter Higgs revised the Standard Model to explain why some particles, such as light packets called photons, are less dense, while others do. They believe that the energy field in the universe meets particles in two different ways. In quantum field theory, matter particles (fermions, such as electrons or quarks within protons) and co-carrying carriers (bosons, such as photons or gluons attached to quarks) are both manifestations of the quantum field. The General Model describes how these three basic particles and forces are related.

Everything in the universe is made up of basic particles, which are governed by four basic forces. For example, electrons, protons, and neutrons are subatomic particles that makeup atoms. The Higgs boson particle is important to the Standard Model because it demonstrates the existence of the Higgs field, an invisible field of energy that exists throughout the universe that provides mass in some particles. The Higgs boson particle is important to the Standard Model because it demonstrates the existence of the Higgs field, an invisible field of energy that exists throughout the universe that provides mass in some particles.

In 2012, scientists confirmed the discovery of the Higgs boson, in the Large Hadron Collider (LHC), the world's most powerful particle accelerator. After decades of research, LHC researchers announced in 2012 that they had discovered a new particle such as the Higgs boson, an award-winning Englert and Higgs 2013 Nobel Prize in Physics. Three years ago, scientists in Geneva, Switzerland, announced the existence of the Higgs Boson, an invisible particle that was once believed to exist. They are fundamental elements of the universe. The discovery of the Higgs boson in 2012 confirmed the theoretical work of generations of physicists.

Higgs boson doomsday theory, in which quantum fluctuations create an empty "bubble" that stretches across the atmosphere and destroys the universe, has long existed. At an AAAS meeting in Boston yesterday, physicist Joseph Lykken said that the mass of Higgs-like, combined with the data present in other subatomic particles, suggests that the universe is currently in an unstable state. A situation that will eventually be overshadowed by another similar atmosphere.

Interestingly, this bubble at the end of the universe would not have existed had it not been for the special weight of the Higgs boson associated with another heavy particle, the upper quark, which is made up of many atoms. If the quarks or Higgs were simple, those destructive bumps would not form. "Even if the Higgs field inside the bubble were much stronger than it is now, it could suppress atoms, destroy their nuclei, and make hydrogen the only thing that exists in the universe," Judith explained in her TED speech.

In a fraction of a second, the bubble would grow and cover the entire visible surface, Moss said. This could mean that the universe may have a catastrophic vacuum rot, with a real vacuum bubble growing at the speed of light.

Another possibility, however, is that the Higgs field may undergo a process called quantum tunneling, which would allow it to reach its next state of energy by penetrating the valley walls through a process called vacuum decay, without major jetting. power is required. If our understanding is correct, the universe would be in a stable state of space, but also a state of low energy through the process of quantum tunneling. If the current environment could move beyond this state of low energy, it is not yet stable, and switching to a new environment could destroy all the particles that exist today.

This means that our atmosphere is destined to one day experience catastrophic failures caused by quantum fluctuations that create a vacuum “bubble” that will stretch and clear the universe and everything in it as we know it. So, from our best understanding, the universe could collapse. This quantum variation can occur somewhere in the space between galaxies and create a growing "bubble", Lykken said.

Theoretical physicians also pointed out before the discovery of the Higgs particles that its large size implies that a low energy level exists. However, particle physicians have calculated that the Higgs field may not be below its stable energy level, given the typical model of particles they now know and the mass measured by the Higgs boson. Physicists have recently written about this possibility because if (a) it is assumed that the species we have identified so far are the only ones affecting the Higgs field, and (b) no other significant forces affecting the Higgs field. In addition to those we know, then you can be sure (although this degree is contradictory) that (1) the Higgs field can reduce the force of the universe by suddenly jumping from ON to SUPER-DUPER ON MODE, and (2) time to wait for this it happens automatically does not end. It will also increase the strength needed to attract the Higgs boson, preventing any instability that could lead to the collapse of the original universe.

Originally thought to define only a large number of W and Z bosons, scientists soon discovered that they could extend the Braut-Englert-Higgs method to define the mass of all the major basic particles. As a result, theorists often view Higgs' camp as "metastable," temporarily holding on to a false vacuum, and while falls are a problem in principle, there is no concern about performance. But it also supports the idea of ​​a possible death bomb, indicating that the so-called Higgs field is ubiquitous, giving particles weight.

Tests to find the Higgs boson has shown that it weighs 125 billion electron volts, more than 130 times the weight of the proton. So a simple argument works this way: Higgs particles fill the space equally or less, with a much larger mass, about 126 times the size of a proton (the basic structure of atoms). Its precise size - 126 times larger than the proton - makes the universe unusable.

With the discovery of the Higgs field, we can ask whether the universe as a quantum system is in a stable, low-energy, or high metastable state. The combination of Higgs mass and high quarks determines whether our atmosphere is stable. Based on our current estimates of maximum mass, our universe is metastable.