Wed. Oct 9th, 2024

The Large Hadron Collider made a revolutionary discovery

The Large Hadron Collider made a revolutionary discovery

The ATLAS experiment at the Large Hadron Collider (LHC) made the first observation of the highest entanglement energy in top and antitop quarks at 13 TeV. Entanglement, an amazing prediction of physics, connects distant objects as if they were connected to each other.

Traditionally seen in photons and low energies, this phenomenon has now been discovered in pairs of top quarks, the heaviest particles known.

The ATLAS experiment at the Large Hadron Collider in Geneva made this revolutionary discovery, expanding the scope of entanglement compared to previous examples. The researchers say they have measured spin entanglement with high precision using data from high-energy proton collisions. This is the first observation of such entanglement in quarks and at the highest energy level.

In everyday life, we think of objects as either separate or interconnected. However, entangled objects are neither truly separate nor physically related; measuring one object instantly reveals information about another, even if they are far from each other.

The researchers demonstrated this phenomenon using photons, and it is a key concept in quantum physics. According to the team, while popular science fiction such as the “Three-Body Problem'' suggests using entanglement for faster-than-light communication, according to quantum theory, this is impossible.

Entanglement, first demonstrated with photons in the 1980s, is now used in technologies such as quantum computing. Recent advances from Geneva extended it to high-energy top quarks, the first observation of entanglement at such extreme energy levels.

200% Deposit Bonus up to €3,000 180% First Deposit Bonus up to $20,000

Matter consists of molecules, which are made up of atoms, with electrons revolving around a dense nucleus – a concept created in 1911. The nucleus contains protons and neutrons, and by the 1970s it was discovered that they were made up of quarks – a total of six types. Among them, the “upper” quark is the heaviest, weighing about 184 times more than a proton and even heavier than a tungsten atom. Its enormous size remains unexplained and is the subject of intense study at the Large Hadron Collider.

Researchers, including those working on the ATLAS experiment in Sydney, are investigating whether such a large mass could be caused by unknown forces or reveal new laws of physics, as current laws of physics seem incomplete. The ATLAS experiment at the Large Hadron Collider, which studies top and antitop quarks produced by proton collisions at 13 TeV, has made it possible to observe entanglement at the highest energies to date.

Researchers were able to identify the spin entanglement by measuring a certain angle between charged leptons from pairs of quarks. By concentrating on stable particles to minimize errors in the simulation models, this measurement, which was made close to the top quark antitope birth barrier, helps ensure accuracy.

With a high degree of reliability, the result showed a significant value of the confusion marker D = -0.537. This is the first time that quark entanglement has been observed at such high energies.

The team argues that entanglement is not specific to top quarks, but rather a widespread phenomenon in quantum physics. Although entanglement can occur in a variety of systems, it is a sensitive process that is often studied at extremely low temperatures to avoid perturbations.

Because the top quark has significant mass, it can be used to study entanglement more effectively , than the other five types of quarks. However, due to the scale of the Large Hadron Collider, top quark pairs are not useful for everyday technology.

Still, scientists say that top quarks are a useful experimental tool and that the study of entanglement is still fascinating, encouraging more research to draw new conclusions.

Natasha Kumar

By Natasha Kumar

Natasha Kumar has been a reporter on the news desk since 2018. Before that she wrote about young adolescence and family dynamics for Styles and was the legal affairs correspondent for the Metro desk. Before joining The Times Hub, Natasha Kumar worked as a staff writer at the Village Voice and a freelancer for Newsday, The Wall Street Journal, GQ and Mirabella. To get in touch, contact me through my natasha@thetimeshub.in 1-800-268-7116

Related Post