Unique Behaviour of Mercury Nuclei Finally Explained
Experimental data of the mean squared charge radius of mercury nuclei (in deviations from the A = 198 nucleus) as a function of mass number. Image: Frank Wienholtz
Back in the 1970s, fluctuations in the size of atomic nuclei were observed during measurements of the optical spectra of electrons in the atomic shells of certain mercury isotopes. The phenomenon was traced to changes of the nuclear shape as a function of mass number A, namely back and forth from slightly oblate to the shape of a rugby ball.
This striking behavior was found below A = 186. There was a big jump of the nuclear radius at A = 185. It reoccurred at the two preceding odd-numbered isotopes, i.e. those with A = 183 and 181, whilst the even-numbered isotopes, A = 184 and 182, followed the general trend.
Only now, more than 40 years later, and by applying cutting-edge research technology, was it possible to answer the two previously unanswered questions: Does this jumping from one nuclear shape to another continue at lower mass numbers? And how can this unique behavior be traced to the internal structure of those nuclei?
The first question has now been answered using new experimental approaches. The challenge was to extend the studies along the entire chain of isotopes down to the short-lived isotopes as far as 177Hg, i.e. to half-lives of just the blink of an eye. To be able to measure this, the experiments had to combine recent technical developments for the first time. This included the use of the Multi-Reflection Time-of-Flight Mass Spectrometer from Greifswald https://idw-online.de/de/news539615, belonging to the ISOLTRAP setup http://isoltrap.web.cern.ch/isoltrap/.
The extremely sensitive and selective detection methods made it possible to show that the special behavior of the mercury isotopes stops at mass numbers below A = 180, where only the “normal”, slightly oblate nuclear shapes are found.
In addition to these experiments, colleagues from theoretical physics performed extensive calculations, which were able to trace the observed behavior back to certain quantum mechanical states of the protons and neutrons in the nuclei. Thus, it was not only the four-decade-long puzzle concerning the neutron-deficient mercury nuclei that was solved. In addition, the results demonstrate the reliability of the nuclear calculations that can now also be applied with confidence to other regions of the nuclear chart, the “periodic system of atomic nuclei”.
Apart from the Atomic and Molecular Physics Research https://physik.uni-greifswald.de/ag-schweikhard/ group at the University of Greifswald’s Institute of Physics, further ISOLTRAP-collaboration members from CERN http://home.cern/, from the Max-Planck-Institut für Kernphysik in Heidelberg https://www.mpi-hd.mpg.de/mpi/start/, as well as from the Universities of Dresden https://tu-dresden.de/, Manchester (Great Britain) http://www.manchester.ac.uk/ and Paris-Sud (France) http://www.u-psud.fr/ contributed. Furthermore, several other groups were involved in the experiments, including laser spectroscopists from the University of Mainz http://www.uni-mainz.de/.
Further information:
CERN press release https://home.cern/about/updates/2018/10/isolde-reveals-shape-shifting-character-…
Mercurial nuclei get back in shape, B.A. Marsh, T. Day Goodacre, S. Sels, Y. Tsunoda, B. Andel, A.N. Andreyev, N.A. Althubiti, D. Atanasov, A.E. Barzakh, J. Billowes, K. Blaum, T. E. Cocolios, J. G. Cubiss, J. Dobaczewski, G.J. Farooq-Smith, D.V. Fedorov, V.N. Fedosseev, K.T. Flanagan, L.P. Gaffney, L. Ghys, M. Huyse, S. Kreim, D. Lunney, K.M. Lynch, V. Manea, Y. Martinez Palenzuela, P.L. Molkanov, T. Otsuka, A. Pastore, M. Rosenbusch, R.E. Rossel, S. Rothe, L. Schweikhard, M.D. Seliverstov, P. Spagnoletti, C. van Beveren, P. van Duppen, M. Veinhard, E. Verstraelen, A. Welker, K. Wendt, F. Wienholtz, R.N. Wolf, A. Zadvornaya, K. Zuber,
Nature Physics http://www.nature.com/articles/s41567-018-0292-8
The images can be downloaded and used for free for editorial purposes in combination with this press release. You must name the respective author of the image.
Contacts
Dipl.-Phys. Frank Wienholtz (CERN Fellow) and
Prof. Dr. Lutz Schweikhard (Head of the Greifswald research group)
Institute of Physics, University of Greifswald
Felix-Hausdorff-Straße 6, D-17487 Greifswald
Tel.: +49 3834 420 4700
wienholtz@physik.uni-greifswald.de, lschweik@physik.uni-greifswald.de
https://physik.uni-greifswald.de/ag-schweikhard/
Prof. Dr. Klaus Blaum (Spokesperson oft he ISOLTRAP collaboration)
Max-Planck-Institut für Kernphysik
Saupfercheckweg 1, D-69117 Heidelberg
Tel.: +49 6221 516850
klaus.blaum@mpi-hd.mpg.de
http://www.mpi-hd.mpg.de/blaum/index.de.htm
Media Contact
All latest news from the category: Physics and Astronomy
This area deals with the fundamental laws and building blocks of nature and how they interact, the properties and the behavior of matter, and research into space and time and their structures.
innovations-report provides in-depth reports and articles on subjects such as astrophysics, laser technologies, nuclear, quantum, particle and solid-state physics, nanotechnologies, planetary research and findings (Mars, Venus) and developments related to the Hubble Telescope.
Newest articles
Eruption of mega-magnetic star lights up nearby galaxy
Thanks to ESA satellites, an international team including UNIGE researchers has detected a giant eruption coming from a magnetar, an extremely magnetic neutron star. While ESA’s satellite INTEGRAL was observing…
Solving the riddle of the sphingolipids in coronary artery disease
Weill Cornell Medicine investigators have uncovered a way to unleash in blood vessels the protective effects of a type of fat-related molecule known as a sphingolipid, suggesting a promising new…
Rocks with the oldest evidence yet of Earth’s magnetic field
The 3.7 billion-year-old rocks may extend the magnetic field’s age by 200 million years. Geologists at MIT and Oxford University have uncovered ancient rocks in Greenland that bear the oldest…
