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Revealing the mysteries of the universe under the skin of an atomic nucleus

Date:
October 12, 2022
Source:
Chalmers University of Technology
Summary:
Massive neutron stars colliding in space are thought to be able to create precious metals such as gold and platinum. The properties of these stars are still an enigma, but the answer may lie beneath the skin of one of the smallest building blocks on Earth -- an atomic nucleus of lead. Getting the nucleus of the atom to reveal the secrets of the strong force that governs the interior of neutron stars has proven difficult. Now a new computer model can provide answers.
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Massive neutron stars colliding in space are thought to be able to create precious metals such as gold and platinum. The properties of these stars are still an enigma, but the answer may lie beneath the skin of one of the smallest building blocks on Earth -- an atomic nucleus of lead. Getting the nucleus of the atom to reveal the secrets of the strong force that governs the interior of neutron stars has proven difficult. Now a new computer model from Chalmers University of Technology, Sweden, can provide answers.

In a recently published article in the scientific journal Nature Physics, Chalmers researchers present a breakthrough in the calculation of the atomic nucleus of the heavy and stable element lead.

The strong force plays the main role

Despite the huge size difference between a microscopic atomic nucleus and a neutron star several kilometers in size, it is largely the same physics that governs their properties. The common denominator is the strong force that holds the particles -- the protons and neutrons -- together in an atomic nucleus. The same force also prevents a neutron star from collapsing. The strong force is fundamental in the universe, but it is difficult to include in computational models, not least when it comes to heavy neutron-rich atomic nuclei such as lead. Therefore, the researchers have wrestled with many unanswered questions in their challenging calculations.

A reliable way to make calculations

"To understand how the strong force works in neutron-rich matter, we need meaningful comparisons between theory and experiment. In addition to the observations made in laboratories and with telescopes, reliable theoretical simulations are therefore also needed. Our breakthrough means that we have been able to carry out such calculations for the heaviest stable element -- lead," says Andreas Ekström, Associate Professor at the Department of Physics at Chalmers and one of the main authors of the article.

The new computer model from Chalmers, developed together with colleagues in North America and England, now shows the way forward. It enables high precision predictions of properties for the isotope* lead-208 and its so-called 'neutron skin'.

The thickness of the skin matters

It is the 126 neutrons in the atomic nucleus that form an outer envelope, which can be described as a skin. How thick the skin is, is linked to the properties of the strong force. By predicting the thickness of the neutron skin, knowledge can increase about how the strong force works -- both in atomic nuclei and in neutron stars.

"We predict that the neutron skin is surprisingly thin, which can provide new insights into the force between the neutrons. A groundbreaking aspect of our model is that it not only provides predictions, but also has the ability to assess theoretical margins of error. This is crucial for being able to make scientific progress," says research leader Christian Forssén, Professor at the Department of Physics at Chalmers.

Model used for the spread of the coronavirus

To develop the new computational model, the researchers have combined theories with existing data from experimental studies. The complex calculations have then been combined with a statistical method previously used to simulate the possible spread of the coronavirus.

With the new model for lead, it is now possible to evaluate different assumptions about the strong force. The model also makes it possible to make predictions for other atomic nuclei, from the lightest to the heaviest.

The breakthrough could lead to much more precise models of, for example, neutron stars and increased knowledge of how these are formed.

"The goal for us is to gain a greater understanding of how the strong force behaves in both neutron stars and atomic nuclei. It takes the research one step closer to understanding how, for example, gold and other elements could be created in neutron stars- and at the end of the day it is about understanding the universe," says Christian Forssén.

During the study, the researchers worked at Chalmers University of Technology in Sweden, Durham University in the UK, University of Washington, Oak Ridge National Laboratory, University of Tennessee and Argonne National Laboratory in the USA and TRIUMF and McGill University in Canada.

*Isotope: An isotope of an element is a variant with a specific number of neutrons.In this case, it is about the isotope lead-208 which has 126 neutrons (and 82 protons).


Story Source:

Materials provided by Chalmers University of Technology. Note: Content may be edited for style and length.


Journal Reference:

  1. Baishan Hu, Weiguang Jiang, Takayuki Miyagi, Zhonghao Sun, Andreas Ekström, Christian Forssén, Gaute Hagen, Jason D. Holt, Thomas Papenbrock, S. Ragnar Stroberg, Ian Vernon. Ab initio predictions link the neutron skin of 208Pb to nuclear forces. Nature Physics, 2022; 18 (10): 1196 DOI: 10.1038/s41567-022-01715-8

Cite This Page:

Chalmers University of Technology. "Revealing the mysteries of the universe under the skin of an atomic nucleus." ScienceDaily. ScienceDaily, 12 October 2022. <www.sciencedaily.com/releases/2022/10/221012103138.htm>.
Chalmers University of Technology. (2022, October 12). Revealing the mysteries of the universe under the skin of an atomic nucleus. ScienceDaily. Retrieved November 20, 2024 from www.sciencedaily.com/releases/2022/10/221012103138.htm
Chalmers University of Technology. "Revealing the mysteries of the universe under the skin of an atomic nucleus." ScienceDaily. www.sciencedaily.com/releases/2022/10/221012103138.htm (accessed November 20, 2024).

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