Protactinium

Mendeleev's periodic table from 1871 with a gap for protactinium at the bottom, between thorium ( Th = 231 ) and uranium ( U = 240 )

In 1900, William Crookes isolated a highly radioactive material from uranium; however, he could not characterize it as a new chemical element and named it Uranium-X (UX). Crookes dissolved uranyl nitrate in ether , the remaining aqueous phase mostly contained the nuclides ²³⁴ Th and ²³⁴ Pa.

^{234 m} Pa was discovered in 1913 by Kasimir Fajans and Oswald Helmuth Göhring , who gave it the name Brevium ( Latin brevis 'short') because of its short half-life (1.17 minutes ).

The long-lived ²³¹ Pa (t _½ = 32,760 years) was found in 1917 by Otto Hahn and Lise Meitner (published in 1918), they called it Protoactinium (from Greek πρῶτος = protos : the first , the preceding , the chemical element that is in the decay series of uranium -235 before the actinium is). Independently, the long-lived isotope was discovered in England by Frederick Soddy and John Arnold Cranston , although the latter could not publish it because he was a soldier in the First World War in 1915.

In 1921 Otto Hahn made the further discovery that there is a second beta-emitting isotope with the same mass number 234 for the brevium 234 found by Fajans, which differs from the brevium only in its longer half-life of 6.7 hours; this is the rare case of nuclear isomerism .

Protactinium was first isolated in 1934 by Aristid von Grosse .

The official name for all three isotopes as well as all artificially produced isotopes with the atomic number 91 was determined by the IUPAC to Protactinium in 1949 , instead of the more difficult to pronounce Protoactinium by Hahn and Meitner.

Occurrence

Protactinium is a radioactive decay product of uranium and is found in nature in the form of the two isotopes ²³¹ Pa and ²³⁴ Pa, whereby the isotope ²³⁴ Pa can occur in two different energy states. Protactinium ²³¹ Pa, an alpha emitter, is created when ²³⁵ U decays (see uranium actinium series ), the beta-emitting protactinium ²³⁴ Pa when uranium ²³⁸ U decays (see uranium radium series ).

Extraction and presentation

Later he also made metallic protactinium from protactinium (V) iodide  (PaI ₅ ).

${\ displaystyle {\ ce {2 PaI5 -> 2 Pa + 5 I2}}}$

In 1959 and 1961, the United Kingdom Atomic Energy Authority (UKAEA) extracted 125 g of protactinium with a purity of 99.9% from 60 t of spent nuclear fuel in a 12-stage process; the cost was about US $ 500,000. For many years this was the only source of Protactinium available worldwide, from which various laboratories were supplied for scientific research.

properties

In the periodic table , protactinium with atomic number 91 is in the series of actinides , its predecessor is thorium , the next element is uranium . Its analogue in the lanthanide series is praseodymium .

Physical Properties

Protactinium is silvery metallic and becomes superconducting below 1.4 K.

Chemical properties

Protactinium occurs mainly in two oxidation states , +4 and +5, both in solids and in solution.

use

Because of its rarity, high level of radioactivity and toxicity, Protactinium has no practical application other than research.

In protactinium ²³¹ Pa, which is formed when uranium ²³⁵ U decays and is also formed in nuclear reactors through the reaction ²³² Th + n →  ²³¹ Th + 2n and subsequent beta decay , a nuclear chain reaction can possibly take place, which in principle also leads to the construction of nuclear weapons could be used. The critical mass is as specified by Walter Seifritz 750 ± 180 kg. Other authors come to the conclusion that a chain reaction is not possible even with any large mass in Protactinium ²³¹ Pa.

Protactinium ²³³ Pa is an intermediate product in the breeding process from thorium ²³² Th to uranium ²³³ U in thorium high-temperature reactors .

${\ displaystyle \ mathrm {^ {232} _ {\ 90} Th \ + \ _ {0} ^ {1} n \ \ longrightarrow \ _ {\ 90} ^ {233} Th \ {\ xrightarrow [{22, 3 \ min}] {\ beta ^ {-}}} \ _ {\ 91} ^ {233} Pa \ {\ xrightarrow [{26,967 \ d}] {\ beta ^ {-}}} \ _ {\ 92 } ^ {233} U}}$

The times given are half-lives .

Since the availability of modern, very sensitive mass spectrometers , it has become possible to use the ²³¹ Pa as a tracer in paleoceanography, for example .

links

→ Category: Protactinium compound

Protactinium (IV) oxide (PaO ₂ ) is a black, crystalline powder. Protactinium (V) oxide (Pa ₂ O ₅ ) is a white, crystalline powder. Both have a cubic crystal system.

Protactinium (V) chloride (PaCl ₅ ) forms yellow monoclinic crystals and has a chain structure consisting of 7-fold coordinated pentagonal bipyramids.

safety instructions

Classifications according to the GHS regulation are not available because they only include chemical hazards which play a completely subordinate role compared to the hazards based on radioactivity . The latter also only applies if the amount of substance involved is relevant.

literature

• Harold W. Kirby: The Radiochemistry of Protactinium. National Academies, 1959 (PDF)
• Boris F. Myasoedov, Harold W. Kirby, Ivan G. Tananaev: Protactinium. In: Lester R. Morss, Norman M. Edelstein, Jean Fuger (Eds.): The Chemistry of the Actinide and Transactinide Elements. Springer, Dordrecht 2006, ISBN 1-4020-3555-1 , pp. 161-252 ( doi: 10.1007 / 1-4020-3598-5_4 ).
• Eric Scerri : A tale of seven elements , Oxford University Press, Oxford, 2013

Web links

Commons : Protactinium  - collection of images, videos and audio files

• Entry to Protactinium. In: Römpp Online . Georg Thieme Verlag, accessed on January 3, 2015.
• Linda Raber: Protactinium , Chemical & Engineering News, 2003

Individual evidence

1. ^ Harry H. Binder: Lexicon of the chemical elements. S. Hirzel Verlag, Stuttgart 1999, ISBN 3-7776-0736-3 .
2. ↑ The values ​​for the properties (info box) are taken from www.webelements.com (Protactinium) , unless otherwise stated .
3. ↑ CIAAW, Standard Atomic Weights Revised 2013 .
4. ↑ ^{a b c d e} Entry on protactinium in Kramida, A., Ralchenko, Yu., Reader, J. and NIST ASD Team (2019): NIST Atomic Spectra Database (ver. 5.7.1) . Ed .: NIST , Gaithersburg, MD. doi : 10.18434 / T4W30F ( https://physics.nist.gov/asd ).  Retrieved June 13, 2020.
5. ↑ ^{a b c d e} entry on protactinium at WebElements, https://www.webelements.com , accessed on June 13, 2020.
6. ↑ The hazards emanating from radioactivity do not belong to the properties to be classified according to the GHS labeling. With regard to other hazards, this element has either not yet been classified or a reliable and citable source has not yet been found.
7. ^ Siegfried Niese : The discovery of the element 91 by Kasimir Fajans and Oswald Göhring in 1913 and the naming by Otto Hahn and Lise Meitner in 1918 (digitized version) .
8. ^ ^{A b} John Emsley: Nature's Building Blocks: An AZ Guide to the Elements. Oxford University Press, Oxford, England, UK 2001, ISBN 0-19-850340-7 , pp. 347-349, chapter: Protactinium ( limited preview in Google book search).
9. ↑ Michael Laing: A Revised Periodic Table: With the Lanthanides Repositioned. In: Foundations of Chemistry . 2005, 7 (3), p. 203 ( doi: 10.1007 / s10698-004-5959-9 ).
10. ^ William Crookes: Radio-Activity of Uranium. In: Proceedings of the Royal Society of London . 1899, 66, pp. 409-423 ( doi: 10.1098 / rspl.1899.0120 ).
11. ^ A Glossary of Terms in Nuclear Science and Technology. P. 180 ( limited preview in Google Book search).
12. ^ Sven Johansson: Decay of UX ₁ , UX ₂ , and UZ. In: Physical Review . 1954, 96 (4), p. 1075 ( doi: 10.1103 / PhysRev.96.1075 ; bibcode : 1954PhRv ... 96.1075J ).
13. ↑ K. Fajans: The position of the radio elements in the periodic system. In: Physikalische Zeitschrift . 1913, 14 (4), pp. 136-142.
14. ^ Kasimir Fajans: Radioactive Transformations and the Periodic System of The Elements. In: Reports of the German Chemical Society . 1913, 46, pp. 422-439.
15. ↑ K. Fajans, O. Göhring: About the complex nature of the UrX. In: The natural sciences . 1913, 1 (14), p. 339. (digi-journals) ; doi: 10.1007 / BF01495360 ; bibcode : 1913NW ...... 1..339F .
16. ↑ K. Fajans, O. Göhring: About the uranium X ₂ - the new element of the uranium series. In: Physikalische Zeitschrift . 1913, 14, pp. 877-884.
17. ↑ Otto Hahn, Lise Meitner: The mother substance of actinium, a new radioactive element of long life. In: Physikalische Zeitschrift . 1918, 19, pp. 208-218 ( doi : 10.1002 / bbpc.19180241107 (currently unavailable) ).
18. ↑ Lise Meitner, Otto Hahn: About the Protactinium and the question of the possibility of its production as a chemical element. In: The natural sciences . 1919, 7 (33), pp. 611-612 ( doi: 10.1007 / BF01498184 ).
19. ^ Protactinium, Jefferson Lab
20. ^ John Albert Cranston, University of Glasgow
21. ↑ Cranston, Soddy, The parent of Actinium, Nature, Volume 100, 1918, pp. 498-499
22. ↑ Otto Hahn: About a new radioactive substance in uranium. In: Reports of the German Chemical Society . 1921, 54 (6), pp. 1131-1142 ( doi: 10.1002 / cber.19210540602 ).
23. ↑ Aristid von Grosse: Das Element 91; its properties and its extraction. In: Reports of the German Chemical Society . 1928, 61 (1), pp. 233-245 ( doi: 10.1002 / cber.19280610137 ).
24. ↑ AV Grosse, MS Agruss: The Isolation of 0.1 gram of the Oxide of Element 91 (Protactinium). In: Journal of the American Chemical Society . 1934, 56 (10), p. 2200 ( doi: 10.1021 / ja01325a507 ).
25. ↑ G. Graue, H. Käding: The technical extraction of Protactinium. In: Angewandte Chemie . 1934, 47 (37), pp. 650-653 ( doi: 10.1002 / anie.19340473706 ).
26. ^ AV Grosse: Metallic Element 91. In: Journal of the American Chemical Society . 1934, 56 (10), pp. 2200-2201 ( doi: 10.1021 / ja01325a508 ).
27. ^ Aristid von Grosse: Element 91. In: Science . 1934, 80 (2084), pp. 512-516 ( doi: 10.1126 / science.80.2084.512 , PMID 17734249 ).
28. ↑ Aristid V. Grosse: For the production of Protactinium. In: Reports of the German Chemical Society . 1935, 68 (2), pp. 307-309 ( doi: 10.1002 / cber.19350680218 ).
29. ↑ David R. Lide (Ed.): CRC Handbook of Chemistry and Physics . 90th edition. (Internet version: 2010), CRC Press / Taylor and Francis, Boca Raton, FL, The Elements "Protactinium", pp. 4-28-4-29.
30. ^ RD Fowler, BT Matthias, LB Asprey, HH Hill, JDG Lindsay, CE Olsen, RW White: Superconductivity of Protactinium. In: Phys. Rev. Lett. 1965, 15 (22), pp. 860-862 ( doi: 10.1103 / PhysRevLett.15.860 ; bibcode : 1965PhRvL..15..860F ).
31. ↑ Walter Seifritz: Nuclear explosive devices - threat or energy supply for mankind. Thiemig-Verlag, 1984, ISBN 3-521-06143-4 .
32. ↑ S. Ganesan, Umasankari Kannan, PD Krishnani, V. Jagannathan, RP Jain, R. Karthikeyan: A Re-calculation of Criticality Property of ²³¹ Pa Using New Nuclear Data. In: Current Science . 1999, 77 (5), pp. 667-671. (PDF) .
33. ↑ JF McManus, R. Francois, J.-M. Gherardi, LD Keigwin, S. Brown-Leger: Collapse and rapid resumption of Atlantic meridional circulation linked to deglacial climate changes. In: Nature . 2004, 428, pp. 834-837 ( doi: 10.1038 / nature02494 ; PDF ).
34. ^ RP Dodge, GS Smith, Q. Johnson, RE Elson: The Crystal Structure of Protactinium Pentachloride. In: Acta Cryst. 1967, 22, pp. 85-89 ( doi: 10.1107 / S0365110X67000155 ).