A new approach to the Hadronization probe via quantum tangle

Recent studies in physics have discovered that quarks and lugs inside protons, which are positive -loaded subatomic particles, have a maximum quantum tangle to high energies. Entrication is a physical phenomenon which implies correlations between distant particles which cannot be explained by theories of classical physics, resulting in the state of a particle influencing that of another.

Researchers at Stony Brook University and the Brookhaven National Laboratory have recently decided to better understand what this recent observation could mean for Hadronization, the process by which quarks and gluons form Hadrons, which can be detected experimentally. Their article, published in Physical examination lettersIntroduce a new approach to probe and study Hadronization by taking advantage of quantum tangle.

“Our study is from intriguing observation that the internal structure of protons to high energies has a maximum quantum tangle,” said Charles Joseph Naim, the corresponding author for the newspaper.

“This concept suggests that quarks and gluons inside a proton are interconnected in such a way that the state of one instantly influence the state of another, whatever the distance. Inspired by this phenomenon, we have sought to explore its implications for Hadronization, the process by which quarks and gluons turned into visible particles detected in experiences.”

The main objective of this recent study by Naim and his colleagues was to better understand how the tangle between quarks and gluons in protons reported in recent studies influences the production of particles in Proton-Protton collisions. The team specifically focused on jets, narrow spraying of particles resulting from high energy collisions.

“To extend our understanding of the maximum entanglement to the production of jet, we have analyzed the data of the Atlas collaboration in the great collision of Hadron (LHC),” said Naim. “This data has provided information on how particles are produced and fragmented in jets.

In their analyzes, Naim and his colleagues compared the derived theoretical predictions using the maximum tangle frame with experimental data collected by the LHC in CERN, the largest particle accelerator in the world. This allowed them to validate their proposed theoretical model and to determine whether quantum tangle could in fact be used to probe the hadronization.

“One of our most important results is the successful application of the maximum quantum tangle concept to explain the models observed in jet production,” said Naim. “This approach offers a new perspective on the transition of quantum chromodynamics disrupting with non -disturbing (QCD), the theory governing the interactions of quarks and gluons.”

This recent study by Naim and his colleagues could soon shed light on future research exploring the quantum nature of Hadronization. Finally, these efforts could help drift more precise predictions for particle physics, while improving the interpretation of future results. The team hopes that the maximum tangle observed will also lead to an understanding of colors containment, one of the most difficult problems of modern science.

“Based on our current work, we plan to study more before the role of quantum entanglement in various processes of Hadronization and possibly in nuclei,” added Naim. “Future research will involve the analysis of the data of future experiences in installations such as the electron-ion collision (EIC), which should provide new information on the behavior of quarks and gluons under different conditions.

“In addition, we aim to develop more sophisticated models incorporating quantum information principles to improve our understanding of particle production mechanisms.”

© 2025 Science X Network