Atomic nuclei consist of nucleons such as protons and neutrons, which are bound together by nuclear force or strong interaction. This force allows protons and neutrons to form bound states; however, when only two neutrons are involved, the attractive force is slightly insufficient to create such a state.
This prompts the question: would four neutrons be adequate? This question has captivated atom physicists, who have actively sought to unlock this mystery in both the theoretical and experimental realms.
With weakly bound nuclei, in which there is no strong attraction from the center, considering two neutrons as a single unit is essential for understanding four-neutron correlations.
Therefore, a research team led by Associate Professor Wataru Horiuchi and Professor Naoyuki Itagaki, from the Osaka Metropolitan University Graduate School of Science, focused on the possibility of enhanced correlations between the two neutron pairs that comprise the four extra neutrons in the helium isotope 8He (8He contains two protons and a total of six neutrons). Their findings were published in Physical Review C.
The team performed extensive quantum mechanics equation calculations and successfully demonstrated the existence of dineutron-dineutron clusters distributed around the 4He core before showing the arrangement these clusters take.
Professor Horiuchi said, “Nuclei with an imbalance of protons and neutrons, such as in 8He, do not naturally exist on Earth but are believed to be generated abundantly in cosmic environments, such as in stars, through the process of nucleosynthesis. Our results provide new insights into the still largely unknown binding forms of neutrons and deepen our understanding of the origins of the elements around us.”
More information:
Y. Yamaguchi et al, Dineutron-dineutron correlation in He8, Physical Review C (2023). DOI: 10.1103/PhysRevC.108.L011304
Provided by
Osaka Metropolitan University
Citation:
Correlation between neutron pairs observed in helium-8 nuclei (2023, August 2)