Ununennium (119Uue) has not yet been synthesised, so all data would be theoretical and a standard atomic weight cannot be given. Like all synthetic elements, it would have no stable isotopes.

List of isotopes

No isotopes of ununennium are known.

Nucleosynthesis

Target-projectile combinations leading to Z=119 compound nuclei

The below table contains various combinations of targets and projectiles that could be used to form compound nuclei with Z=119.[1]

TargetProjectileCNAttempt result
208Pb 87Rb295UueReaction yet to be attempted
209Bi 86Kr295UueReaction yet to be attempted
238U 59Co297UueReaction yet to be attempted
237Np 58Fe295UueReaction yet to be attempted
244Pu 55Mn299UueReaction yet to be attempted
243Am 54Cr297Uue[2]Reaction yet to be attempted
248Cm 51V299UueReaction being attempted
250Cm 51V301UueReaction yet to be attempted
249Bk 50Ti299UueFailure to date
249Cf 45Sc294UueReaction yet to be attempted
254Es 48Ca302UueFailure to date

Cold fusion

Following the claimed synthesis of 293Og in 1999 at the Lawrence Berkeley National Laboratory from 208Pb and 86Kr, the analogous reactions 209Bi + 86Kr and 208Pb + 87Rb were proposed for the synthesis of element 119 and its then-unknown alpha decay daughters, elements 117, 115, and 113.[3] The retraction of these results in 2001[4] and more recent calculations on the cross sections for "cold" fusion reactions cast doubt on this possibility; for example, a maximum yield of 2 fb is predicted for the production of 294Uue in the former reaction.[5] Radioactive ion beams may provide an alternative method utilizing a lead or bismuth target, and may enable the production of more neutron-rich isotopes should they become available at required intensities.[5]

Hot fusion

243Am(54Cr,xn)297−xUue

There are indications that the team at the Joint Institute for Nuclear Research (JINR) in Russia plans to try this reaction in the future. The product of the 3n channel would be 294Uue; its expected granddaughter 286Mc was synthesised in a preparatory experiment at the JINR in 2021, using the reaction 243Am(48Ca,5n)286Mc.[2]

248Cm(51V,xn)299−xUue

The team at RIKEN in Wakō, Japan began bombarding curium-248 targets with a vanadium-51 beam in January 2018[6] to search for element 119. Curium was chosen as a target, rather than heavier berkelium or californium, as these heavier targets are difficult to prepare.[7] The reduced asymmetry of the reaction is expected to approximately halve the cross section, requiring a sensitivity "on the order of at least 30 fb".[8] The 248Cm targets were provided by Oak Ridge National Laboratory. RIKEN developed a high-intensity vanadium beam.[9] The experiment began at a cyclotron while RIKEN upgraded its linear accelerators; the upgrade was completed in 2020.[10] Bombardment may be continued with both machines until the first event is observed; the experiment is currently running intermittently for at least 100 days per year.[11][7] The RIKEN team's efforts are being financed by the Emperor of Japan.[12]

248
96
Cm
+ 51
23
V
299
119
Uue
* → no atoms yet

The produced isotopes of ununennium are expected to undergo two alpha decays to known isotopes of moscovium (288Mc and 287Mc respectively),[6] which would anchor them to a known sequence of five further alpha decays and corroborate their production. In 2022, the optimal reaction energy for synthesis of ununennium in this reaction was experimentally estimated as 234.8±1.8 MeV at RIKEN.[13] The cross section is probably below 10 fb.[9]

249Bk(50Ti,xn)299−xUue

From April to September 2012, an attempt to synthesize the isotopes 295Uue and 296Uue was made by bombarding a target of berkelium-249 with titanium-50 at the GSI Helmholtz Centre for Heavy Ion Research in Darmstadt, Germany.[14][15] This reaction between 249Bk and 50Ti was predicted to be the most favorable practical reaction for formation of ununennium,[15] as it is rather asymmetrical,[16] though also somewhat cold.[17] (The reaction between 254Es and 48Ca would be superior, but preparing milligram quantities of 254Es for a target is difficult.)[16] Moreover, as berkelium-249 decays to californium-249 (the next element) with a short half-life of 327 days, this allowed elements 119 and 120 to be searched for simultaneously.[8] Nevertheless, the necessary change from the "silver bullet" 48Ca to 50Ti divides the expected yield of ununennium by about twenty, as the yield is strongly dependent on the asymmetry of the fusion reaction.[16] Due to the predicted short half-lives, the GSI team used new "fast" electronics capable of registering decay events within microseconds.[15][16]

249
97
Bk
+ 50
22
Ti
299
119
Uue
* → no atoms
249
98
Cf
+ 50
22
Ti
299
120
Ubn
* → no atoms

Neither element 119 nor element 120 was observed. This implied a limiting cross-section of 65 fb for producing element 119 in these reactions, and 200 fb for element 120.[17][8] The predicted actual cross section for producing element 119 in this reaction is around 40 fb, which is at the limits of current technology.[16] (The record lowest cross section of an experimentally successful reaction is 30 fb for the reaction between 209Bi and 70Zn producing nihonium.)[16] The experiment was originally planned to continue to November 2012,[18] but was stopped early to make use of the 249Bk target to confirm the synthesis of tennessine (thus changing the projectiles to 48Ca).[17]

The team at the Joint Institute for Nuclear Research in Dubna, Russia, planned to attempt this reaction.[19][20][21][22][23][24] Currently, beams heavier than 48Ca have not been used at the JINR, but they are actively being developed.[9]

254Es(48Ca,xn)302−xUue

The synthesis of ununennium was first attempted in 1985 by bombarding a sub-microgram target of einsteinium-254 with calcium-48 ions at the superHILAC accelerator at Berkeley, California:

254
99
Es
+ 48
20
Ca
302
119
Uue
* → no atoms

No atoms were identified, leading to a limiting cross section of 300 nb.[25] Later calculations suggest that the cross section of the 3n reaction (which would result in 299Uue and three neutrons as products) would actually be six hundred thousand times lower than this upper bound, at 0.5 pb.[26] Tens of milligrams of einsteinium, an amount that cannot presently be produced, would be needed for this reaction to have a reasonable chance of succeeding.[9]

References

  • Isotope masses from:
    • M. Wang; G. Audi; A. H. Wapstra; F. G. Kondev; M. MacCormick; X. Xu; et al. (2012). "The AME2012 atomic mass evaluation (II). Tables, graphs and references" (PDF). Chinese Physics C. 36 (12): 1603–2014. Bibcode:2012ChPhC..36....3M. doi:10.1088/1674-1137/36/12/003. S2CID 250839471.
    • Audi, Georges; Bersillon, Olivier; Blachot, Jean; Wapstra, Aaldert Hendrik (2003), "The NUBASE evaluation of nuclear and decay properties", Nuclear Physics A, 729: 3–128, Bibcode:2003NuPhA.729....3A, doi:10.1016/j.nuclphysa.2003.11.001
  1. Isospin dependence in heavy-element synthesis in fusion-evaporation reactions with neutron-rich radioactive ion-beams, A. Yakushev et al.
  2. 1 2 "Superheavy Element Factory: overview of obtained results". Joint Institute for Nuclear Research. 24 August 2023. Retrieved 7 December 2023.
  3. Hoffman, Ghiorso & Seaborg 2000, p. 431.
  4. Public Affairs Department (21 July 2001). "Results of element 118 experiment retracted". Berkeley Lab. Archived from the original on 29 January 2008. Retrieved 18 January 2008.
  5. 1 2 Loveland, W. (2007). "Synthesis of transactinide nuclei using radioactive beams" (PDF). Physical Review C. 76 (1). 014612. Bibcode:2007PhRvC..76a4612L. doi:10.1103/PhysRevC.76.014612.
  6. 1 2 Sakai, Hideyuki; Haba, Hiromitsu; Morimoto, Kouji; Sakamoto, Naruhiko (9 December 2022). "Facility upgrade for superheavy-element research at RIKEN". The European Physical Journal A. 58 (238): 238. Bibcode:2022EPJA...58..238S. doi:10.1140/epja/s10050-022-00888-3. PMC 9734366. PMID 36533209. S2CID 254530675.
  7. 1 2 Sakai, Hideyuki (27 February 2019). "Search for a New Element at RIKEN Nishina Center" (PDF). infn.it. Retrieved 17 December 2019.
  8. 1 2 3 Khuyagbaatar, J.; Yakushev, A.; Düllmann, Ch. E.; et al. (2020). "Search for elements 119 and 120" (PDF). Physical Review C. 102 (6). 064602. Bibcode:2020PhRvC.102f4602K. doi:10.1103/PhysRevC.102.064602. hdl:1885/289860. S2CID 229401931. Retrieved 25 January 2021.
  9. 1 2 3 4 Gates, J.; Pore, J.; Crawford, H.; Shaughnessy, D.; Stoyer, M. A. (25 October 2022). "The Status and Ambitions of the US Heavy Element Program". osti.gov. doi:10.2172/1896856. OSTI 1896856. S2CID 253391052. Retrieved 13 November 2022.
  10. Sakurai, Hiroyoshi (1 April 2020). "Greeting | RIKEN Nishina Center". With the completion of the upgrade of the linear accelerator and BigRIPS at the beginning of 2020, the RNC aims to synthesize new elements from element 119 and beyond.
  11. Ball, P. (2019). "Extreme chemistry: experiments at the edge of the periodic table" (PDF). Nature. 565 (7741): 552–555. Bibcode:2019Natur.565..552B. doi:10.1038/d41586-019-00285-9. ISSN 1476-4687. PMID 30700884. S2CID 59524524. We started the search for element 119 last June," says RIKEN researcher Hideto En'yo. "It will certainly take a long time — years and years — so we will continue the same experiment intermittently for 100 or more days per year, until we or somebody else discovers it.
  12. Chapman, Kit; Turner, Kristy (13 February 2018). "The hunt is on". Education in Chemistry. Royal Society of Chemistry. Retrieved 28 June 2019. The hunt for element 113 was almost abandoned because of lack of resources, but this time Japan's emperor is bankrolling Riken's efforts to extend the periodic table to its eighth row.
  13. Tanaka, Masaomi; Brionnet, Pierre; Du, Miting; et al. (2022). "Probing Optimal Reaction Energy for Synthesis of Element 119 from 51V+248Cm Reaction with Quasielastic Barrier Distribution Measurement". Journal of the Physical Society of Japan. 91 (8): 042081–1–11. Bibcode:2022JPSJ...91h4201T. doi:10.7566/JPSJ.91.084201. S2CID 250399446.
  14. Modern alchemy: Turning a line, The Economist, May 12, 2012.
  15. 1 2 3 DÜLLMANN, CHRISTOPH E. (2013). "Superheavy Element Research at Tasca at Gsi". Fission and Properties of Neutron-Rich Nuclei. WORLD SCIENTIFIC: 271–277. doi:10.1142/9789814525435_0029. ISBN 978-981-4525-42-8. Retrieved 21 March 2022.
  16. 1 2 3 4 5 6 Zagrebaev, Karpov & Greiner 2013.
  17. 1 2 3 http://asrc.jaea.go.jp/soshiki/gr/chiba_gr/workshop3/&Yakushev.pdf
  18. "Search for element 119: Christoph E. Düllmann for the TASCA E119 collaboration" (PDF). Archived from the original (PDF) on 2016-03-04. Retrieved 2015-09-15.
  19. "Scientists will begin experiments on the synthesis of element 119 in 2019". www.jinr.ru. JINR. 28 September 2016. Retrieved 31 March 2017. "The discovery of elements 115, 117 and 118 is an accomplished fact; they were placed in the periodic table, though still unnamed and will be confirmed only at the end of the year. The D.I.Mendeleev Periodic Table is not infinite. In 2019, scientists will begin the synthesis of elements 119 and 120 which are the first in the 8th period," said S.N. Dmitriev.
  20. Dmitriev, Sergey; Itkis, Mikhail; Oganessian, Yuri (2016). Status and perspectives of the Dubna superheavy element factory (PDF). Nobel Symposium NS160 – Chemistry and Physics of Heavy and Superheavy Elements. doi:10.1051/epjconf/201613108001.
  21. "What it takes to make a new element". Chemistry World. Retrieved 2016-12-03.
  22. Roberto, J. B. (31 March 2015). "Actinide Targets for Super-Heavy Element Research" (PDF). cyclotron.tamu.edu. Texas A & M University. Retrieved 28 April 2017.
  23. Morita, Kōsuke (5 February 2016). "The Discovery of Element 113". YouTube. Archived from the original on 2021-11-18. Retrieved 28 April 2017.
  24. Morimoto, Kouji (2016). The discovery of element 113 at RIKEN (PDF). 26th International Nuclear Physics Conference. Retrieved 14 May 2017.
  25. Lougheed, R.; Landrum, J.; Hulet, E.; et al. (3 June 1985). "Search for superheavy elements using the 48Ca + 254Esg reaction". Physical Review C (published 1 November 1985). 32 (5): 1760–1763. Bibcode:1985PhRvC..32.1760L. doi:10.1103/PhysRevC.32.1760. PMID 9953034. Retrieved 21 March 2022.
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