Team solves a beta-decay puzzle with advanced nuclear models by Staff Writers Oak Ridge TN (SPX) Mar 13, 2019
An international collaboration including scientists at the Department of Energy's (DOE's) Oak Ridge National Laboratory (ORNL) solved a 50-year-old puzzle that explains why beta decays of atomic nuclei are slower than what is expected based on the beta decays of free neutrons. The findings, published in Nature Physics, fill a long-standing gap in physicists' understanding of beta decay, an important process stars use to create heavier elements, and emphasize the need to include subtle effects - or more realistic physics - when predicting certain nuclear processes. "For decades, scientists have lacked a first-principles understanding of nuclear beta decay, in which protons convert into neutrons, or vice versa, to form other elements," said ORNL staff scientist Gaute Hagen, who led the study. "Our team demonstrated that theoretical models and computation have progressed to the point where it is possible to calculate some decay properties with enough precision to allow for direct comparison to experiment." To solve the problem, the team simulated tin-100 decaying into indium-100, a neighboring element on the periodic table. The two elements share the same number of nucleons (protons and neutrons), with tin-100 possessing 50 protons to indium-100's 49. Calculating beta decay precisely required the team to not only accurately simulate the structure of the mother and daughter nuclei but also account for the interactions between two nucleons during the transition. This additional treatment presented an extreme computational challenge due to the combination of strong nuclear correlations and interactions involving the decaying nucleon. In the past, nuclear physicists worked around this problem by inserting a fundamental constant to reconcile observed beta-decay rates of neutrons inside and outside the nucleus, a practice known as "quenching." But with machines like ORNL's Titan supercomputer, Hagen's team demonstrated that this mathematical crutch is no longer necessary. "Nobody really understood why this quenching factor worked. It just did," said ORNL computational scientist Gustav Jansen. "We found that it could largely be explained by including two nucleons in the decay - for example, two protons decaying into a proton and a neutron, or a proton and a neutron decaying into two neutrons." The team, which included partners from Lawrence Livermore National Laboratory, University of Tennessee, University of Washington, TRIUMF (Canada), and Technical University Darmstadt (Germany), performed a comprehensive study of beta decays from light to medium-heavy nuclei up to tin-100. The achievement gives nuclear physicists increased confidence as they search for answers to some of the most perplexing mysteries related to the formation of matter in the universe. Beyond regular beta decay, scientists are looking to compute neutrinoless double beta decay, a theorized form of nuclear decay that, if observed, would explore important new physics and help to determine the mass of the neutrino.
Tin to In In neutron beta decay, an electron and an anti-neutrino are emitted. When tin-100 transforms into indium-100, the nucleus undergoes beta-plus decay, expelling a positron and a neutrino when converting a proton to a neutron. With its equal number of protons and neutrons, tin-100 exhibits an unusually high rate of beta decay, giving the ORNL team a strong signal from which to verify its results. Furthermore, the tin-100 nucleus is "doubly magic," meaning the nucleons fill out defined shells inside the nucleus that make it strongly bound and relatively simple in structure. The ORNL team's NUCCOR code, which is programmed to solve the nuclear many-body problem, excels at describing doubly magic nuclei up and down the nuclear chart. "A doubly magic nucleus like tin-100 isn't as complicated as many other nuclei," said Thomas Papenbrock, a researcher at the University of Tennessee and ORNL. "This means we can reliably compute it using our coupled cluster method, which calculates properties of large nuclei by accounting for forces between the individual nucleons." To model beta decay, however, the team also had to calculate the structure of indium-100, a more complex nucleus than the doubly magic tin-100. This required a more precise treatment of the strong correlations between the nucleons. By borrowing ideas from quantum chemistry, which treats electrons as waves, Hagen's team successfully developed techniques to model these processes. "In our case we are dealing with nucleons instead of electrons, but the quantum chemistry concepts have helped us branch out from doubly magic nuclei and expand into these open-shell regions," said ORNL physicist Titus Morris.
Guiding experiment Researchers are currently using Summit to simulate how calcium-48, another doubly magic nucleus, would undergo neutrinoless double beta decay - a process in which two neutrons beta decay into protons, but without emitting any neutrinos. The results could aid experimentalists in the selection of an optimal detector material for the potential discovery of this rare phenomenon. "Currently, calculations using different nuclear models of neutrinoless double beta decay may differ by as much as a factor of six," Hagen said. "Our goal is to provide a benchmark for other models and theories."
Fukushima evacuees resist return as 'Reconstruction Olympics' near Tokyo (AFP) March 8, 2019 With Japan keen to flaunt Tokyo 2020 as the "Reconstruction Olympics", people who fled the Fukushima nuclear disaster are being urged to return home but not everyone is eager to go. Tokyo and the International Olympic Committee (IOC) plan to use the global spotlight from the Games to showcase the recovery of the region devastated by the 2011 nuclear disaster and the tsunami that triggered it, killing 18,000 people. But Kazuko Nihei, who fled her home in Fukushima city with her two daughters in 2 ... read more
|
|
The content herein, unless otherwise known to be public domain, are Copyright 1995-2024 - Space Media Network. All websites are published in Australia and are solely subject to Australian law and governed by Fair Use principals for news reporting and research purposes. AFP, UPI and IANS news wire stories are copyright Agence France-Presse, United Press International and Indo-Asia News Service. ESA news reports are copyright European Space Agency. All NASA sourced material is public domain. Additional copyrights may apply in whole or part to other bona fide parties. All articles labeled "by Staff Writers" include reports supplied to Space Media Network by industry news wires, PR agencies, corporate press officers and the like. Such articles are individually curated and edited by Space Media Network staff on the basis of the report's information value to our industry and professional readership. Advertising does not imply endorsement, agreement or approval of any opinions, statements or information provided by Space Media Network on any Web page published or hosted by Space Media Network. General Data Protection Regulation (GDPR) Statement Our advertisers use various cookies and the like to deliver the best ad banner available at one time. All network advertising suppliers have GDPR policies (Legitimate Interest) that conform with EU regulations for data collection. By using our websites you consent to cookie based advertising. If you do not agree with this then you must stop using the websites from May 25, 2018. Privacy Statement. Additional information can be found here at About Us. |