Never done before: A new way of studying quarks

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Never done before: A new way of studying quarks

Scientists are studying how matter obtains its mass by including quarks.


Never done before: A new way of studying quarks

"Conclusive evidence that extreme stress caused the meltdown is still unknown," Fukushima said.

"The downside is that QCD describes things in a way that makes theoretical calculations difficult. Pressure can have an effect on the masked angular velocities of quarks, which in inversion can appear as real values for elements we can control. In a very certain quarter of l. a. dependence on fast quarks once To find strategies to show our concept in the experiment.


A novel method has been proposed to study quarks, the fundamental particles that make up protons and neutrons in atomic nuclei.


This innovative approach has never been attempted before and could provide answers to many fundamental questions in physics, particularly the origin of mass in the matter.


familiar but different arrangements of components that are smaller and more difficult to explore than those above.


On our everyday scale, we have objects we can see and touch. Whether it's water in a glass or the glass itself, they are mostly assemblies of molecules too small to see.


The tools of physics, microscopes, particle accelerators, etc. Go ahead, let's take a deeper look to reveal that molecules are made up of atoms.


But that's not all: Atoms consist of a nucleus surrounded by electrons.


The nucleus, in turn, is an assembly of nucleons (protons and neutrons) that give the atom its properties and mass.


But it doesn't end here either; Nucleons are also made up of lesser-known things known as quarks and gluons.


And it is precisely on this scale that the frontiers of our knowledge of basic physics represent a blockage.


As far as the study of quarks and gluons is concerned, ideally, they should be isolated from one another; however,  this currently seems impossible.


For particle accelerators when atoms are smashed and showers of atomic debris are created, quarks and gluons snap back together too quickly for researchers to study in detail.


New research from the Tokyo University  Physics Institute suggests that we may soon unlock the next layer of matryoshka dolls: "To better understand our material world, we need to conduct experiments and improve experiments, we need to explore new approaches to it as we do.


" doing things,” said Professor Kenji Fukushima.


"We have outlined a possible way to identify the mechanism responsible for the confinement of the quarks.


This is a long-standing problem in physics, and if solved, it could reveal some deep mysteries about the matter and structure of the universe.


The mass of subatomic quarks is incredibly small: together, the quarks in a nucleon account for less than 2% of the total mass, and gluons appear to be completely massless.


Therefore, physicists propose that most of the atomic mass comes from how quarks and gluons are bound together, and not from the things themselves.


They are connected by what is called the strong force, one of the four fundamental forces of nature, including electromagnetism and gravity, and the strong force is thought to give mass to even a nucleon.


This is part of a theory known as Quantum Chromodynamics (QCD), where "chromium" comes from the Greek word for color, which is why quarks are sometimes heard to be red, green, or blue despite being colorless.


Our success is to reveal that beneath neath certain instances, the robust pressure can carry out the confinement of quarks.


We did this by decoding a few found quark parameters as a brand new variable, which we call imaginary angular velocity.


Although it's far merely mathematical, it may be converted again to actual values ​​of factors we will control.


This must cause a way of knowing an extraordinarily speedy spinning quark kingdom of dependence as soon as we discover ways to flip our concept into an experiment.


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