The failed test marks the beginning of a new collapse within the International of physics

 

A 12-foot-long [12 m] microbone detector is stored in a large cryogenic (bloodless) tank filled with 150 tons of liquid argon at temperatures below 186 degrees Celsius.

Scientists who have discovered a simple molecule that has been used in the construction of the universe say that a new eruption has begun in natural sciences.

a major test was achieved to test the subatomic particle, the main fabric matter that makes up our daily lives.

Experiments found no particle known as sterile neutrino.

we are now going to be physicists who are working on new theories about the creation of the universe.

Professor Mark Thomson of the Council for Technology and Technology (STFC), the United Kingdom, is investing in microbone experiments, which he described as "very important" findings.

this is because a large number of physicists are fully based on their theories during the existence of sterile neutrinos.

"The idea has been around for a long time and there is a lot of entertainment," Professor Thomson told .

"This result is undoubtedly exciting because it could contribute to new emerging ideas in the field of particle physics and cosmology."

Microbone testing was performed at the American-based totally Fermi country wide Accelerator Laboratory in Illinois. but physicists from many lands are concerned.

Microbone electric racks are placed on the platform just above the detector blocking the amount of cosmic radiation or radiation in the universe affecting the results.

There are subatomic debris or subatomic particles scattered throughout the neutrino universe, but they rarely interfere with the normal earth. They are passing through the earth with billions of people every second.

There are 3 types: electron, mouse and tau. In 1998, oriental scientists decided to regenerate neutrinos from one species to any other at a particular stage in the journey.

This process of conversion cannot be explained by the modern “great principle” of subatomic physics called the same old model. some physicists hope that discovering why neutrinos are so small will help us to capture the current device of the universe and how it came to be. weight loss is due to the ability of neutrinos to change the condition.

Antimatter or antidote 

According to current theories, the amount of matter and antimatter was equal immediately after the Big Bang. However, when matter and antimatter collide, they wipe out each other vigorously, releasing energy. If the two were equal in the universe, they should have eliminated each other.

Instead, most of the universe today is made up of matter and the amount of antimatter is very small.

Some scientists believe that the ability of neutrinos to change their shape is due to the agility of the universe, which has resulted in the remaining amount of matter after the Big Bang to form planets, stars and galaxies.

In 1990, the US Department of Energy experimented with a liquid-centrifugal neutrino detector at the Los Alamos National Laboratory in New Mexico, producing far more electrons and neutrinos than could be seen from the three-dimensional theory of neutrinos. Could Later, another experiment in 2002 confirmed this result.

Physicists have suggested the existence of a fourth type and called it sterile neutrino. He thought that this particle would explain the formation of large quantities of electrons and neutrinos, and also explain why these particles change shape.

They are called sterile or sterile neutrinos because they do not interact with matter in any way, while other neutrinos, although less able to do so, are capable of doing so. The discovery of sterile neutrinos in subatomic physics would be larger than the Higgs boson because, unlike other states of neutrinos and Higgs particles, it is not part of the current standard model of physics.

To find sterile neutrinos, a team of about 200 scientists from five countries developed a microbooster neutrino experiment, or microbone, that holds 150 tons of machines in a space the size of a large truck.

Its detectors are very sensitive and its observations in the subatomic world are exemplified by the ultra-high definition of an object.

The team has now announced that four separate analyzes of the data from the experiment have concluded that "no trace" of sterile neutrinos has been found.

A new chapter

But the result did not end there, but opened a new chapter.

Fermelib's Dr. Sam Zeller says the lack of clues does not mean a refutation of previous information.

"Previous information does not lie," he said. 

"There is a very interesting process going on that we need to understand. New information is taking us in a new direction with possible justifications and pointing to something more complex and interesting. It's very exciting. "

Justin Evans, a professor at the University of Manchester, believes that the new puzzle created by this information is a turning point in research on neutrinos.

"Every time we look at a neutrino, we find something new or unexpected," he said.

"The results of the microbiome are taking us in a new direction and our neutrino program will take us to the bottom of some puzzles."