Ida Noddack

Ida Noddack (25 February 1896 – 24 September 1978), née Tacke, was a German chemist and physicist. In 1934 she was the first to mention the idea later named nuclear fission.[2] With her husband - Walter Noddack - and Otto Berg she discovered element 75, rhenium. She was nominated three times for the Nobel Prize in Chemistry.[3]

Ida Noddack
Born
Ida Tacke

25 February 1896
Died24 September 1978(1978-09-24) (aged 82)
CitizenshipGermany
Alma materTechnical University of Berlin[1]
Known forRhenium, nuclear fission
AwardsLiebig Medal
Scheele Medal[1]
Scientific career
FieldsChemist and physicist
InstitutionsAllgemein Elektrizität Gesellschaft, Berlin; Siemens & Halske, Berlin; Physikalische Technische Reichsanstalt, Berlin; University of Freiburg, University of Strasbourg; Staatliche Forschungs Institut für Geochemie, Bamberg[1]

Background

Ida Tacke was born in Lackhausen (nowadays a part of the city of Wesel) in the northern Rhine region in 1896. She described how she picked her path of study by stating, "since I did not want to be a teacher at all, and research and industry employed proportionally fewer physicists at that time, I decided to become a chemist– a decision that was welcomed by my father who owned a small varnish factory in the Lower Rhine region."[4] She chose to attend the Technical University of Berlin because she was drawn to its long and demanding programs. She entered the school in 1915, six years after women were allowed to study in all of Berlin's universities. Nine out of the eighty-five members of her class studied chemistry.[5] In 1918, she graduated from the University with a degree in chemical and metallurgical engineering, specifically on higher aliphatic fatty acid anhydrides.[6] She was one of the first women in Germany to study chemistry, and she was a part of one of the first generations of female students in Germany. In addition, the percent of women studying chemistry increased from 3% before World War I to 35% during the war.[5] After graduating, she worked in the chemistry laboratory of the Berlin turbine factory of AEG, which is a company that is affiliated with General Electric in the United States.[6]

The building she worked in, designed by Peter Behrens, was world-famous and resembled a turbine. She met her husband, Walter Noddack, at the Technical University of Berlin while he was working as a researcher.[6] They were married in 1926.[7] Both before and after their marriage they worked as partners, an "Arbeitsgemeinschaft" or "work unit."[8]

Nuclear fission

Noddack correctly criticized Enrico Fermi's chemical proofs in his 1934 neutron bombardment experiments, from which he postulated that transuranic elements might have been produced. This theory was widely accepted for a few years. However, Noddack's paper "On Element 93" suggested a number of possibilities, but centered on Fermi's failure to chemically eliminate all lighter than uranium elements in his proofs, rather than only down to lead.[9] The paper is considered historically significant today not simply because she correctly pointed out the flaw in Fermi's chemical proof but because she suggested the possibility that "it is conceivable that the nucleus breaks up into several large fragments, which would of course be isotopes of known elements but would not be neighbors of the irradiated element."[10] In doing so she presaged what would become known a few years later as nuclear fission. However, Noddack's theory did not exhibit experimental proof or a theoretical basis for this possibility. Therefore, the paper was generally ignored and mocked by others, despite the fact that she was correct.[11] Several German scientists, like Otto Hahn, saw Noddack's work as "ridiculous."[6] A woman's position in the workplace had been dwindling for years due to the 1929 Wall Street crash. In 1932, a German law, replicating others in Europe, was put into place that obligated married women to leave their jobs and become housewives so that there would be more positions available for men. Noddack was able to escape this law due to her status as an "unpaid collaborator."[6] This may have caused her to be looked down upon by men in the field as she was only able to work due to this loophole.

Noddack's idea of nuclear fission was not confirmed until much later. Experiments along a similar line to Fermi's, by Irène Joliot-Curie, Frédéric Joliot-Curie and Pavle Savić in 1938 raised what they called "interpretational difficulties" when the supposed transuranics exhibited the properties of rare earths rather than those of adjacent elements. Ultimately on December 17, 1938, Otto Hahn and Fritz Strassmann provided chemical proof that the previously presumed transuranic elements were isotopes of barium, and Hahn wrote these exciting results to his exiled colleague Lise Meitner, explaining the process as a 'bursting' of the uranium nucleus into lighter elements. Meitner and Otto Frisch utilized Fritz Kalckar and Niels Bohr's liquid drop hypothesis (first proposed by George Gamow in 1935) to provide a first theoretical model and mathematical proof of what Frisch coined nuclear fission. Frisch also experimentally verified the fission reaction by means of a cloud chamber, confirming the energy release. Therefore, Noddack's original hypothesis was finally accepted.[12][13][14][15][16][17][18][19][20][21]

Element discovery

Noddack and her husband-to-be looked for the then still unknown elements 43 and 75 at the Physikalisch-Technische Reichsanstalt. In 1925, they published a paper (Zwei neue Elemente der Mangangruppe, Chemischer Teil) and called the new elements rhenium (75) and masurium (43). They named the elements rhenium in respect of Ida's birthplace, and masurium in honor of his.[6] After scientists were sceptical of their results, the Noddack's began to perform more experiments to confirm their discoveries. Only rhenium's discovery was confirmed. They were unable to isolate element 43 and their results were not reproducible.[6] These achievements led to Ida being awarded the German Chemical Society's prestigious Liebig Medal in 1931.

Element 43 was definitively isolated in 1937 by Emilio Segrè and Carlo Perrier from a discarded piece of molybdenum foil from a cyclotron which had undergone beta decay. It was eventually named technetium due to its artificial source. No isotope of technetium has a half-life longer than 4.2 million years and was presumed to have disappeared on Earth as a naturally occurring element. In 1961 minute amounts of technetium in pitchblende produced from spontaneous 238U fission were discovered by B. T. Kenna and Paul K. Kuroda.[22] Based on this discovery, Belgian physicist Pieter van Assche constructed an analysis of their data to show that the detection limit of Noddacks' analytical method could have been 1000 times lower than the 10−9 value reported in their paper, in order to show the Noddacks could have been the first to find measurable amounts of element 43, as the ores they had analyzed contained uranium.[23] Using Van Assche's estimates of the Noddacks' residue compositions, NIST scientist John T. Armstrong, simulated the original X-ray spectrum with a computer, and claimed that the results were "surprisingly close to their published spectrum!"[24] Gunter Herrmann from the University of Mainz examined van Assche's arguments, and concluded they were developed ad hoc, and forced to a predetermined result.[25] According to Kenna and Kuroda 99technetium content expected in a typical pitchblende (50% uranium) is about 10 −10 g/kg of ore. F. Habashi pointed out that uranium was never more than about 5% in Noddacks' columbite samples, and the amount of element 43 could not exceed 3 × 10 −11 µg/kg of ore. Such a low quantity could not be weighed, nor give X-ray lines of element 43 clearly distinguishable from the background noise. The only way to detect its presence was to carry out radioactive measurements, a technique the Noddacks were not able to employ, but Segrè and Perrier did.[26][27][28][29][30]

Following on the van Assche and Armstrong claims, an investigation was made into the works of Masataka Ogawa who had made a prior claim to the Noddacks. In 1908 he claimed to have isolated element 43, calling it Nipponium. Using an original plate (not a simulation), Kenji Yoshihara determined Ogawa had not found the Period 5 Group 7 element 43 (eka-manganese), but had successfully separated Period 6 Group 7 element 75 (dvi-manganese) (rhenium), preceding the Noddacks by 17 years.[31][32][33] However this claim has been disputed by chemistry historian Eric Scerri in his book titled "A Tale of Seven Elements" E. R. Scerri (2013). A Tale of Seven Elements. New York;Oxford:Oxford University Press. ISBN 978-0-19-539131-2.

Notable nominations and awards

Ida Noddack was nominated three times for the Nobel Prize in Chemistry due to her discovery of rhenium and masurium. Noddack and her husband were repeatedly nominated for the Nobel Prize in 1932, 1933, 1935 and 1937 (once by Walther Nernst and K. L. Wagner for 1933; both Noddacks were nominated by W. J. Müller for 1935 and by A. Skrabal for 1937).[6] The two of them were also awarded the German Chemical Society's prestigious Liebig Medal in 1931. In 1934, they received the Scheele Medal of the Swedish Chemical Society as well as the German patent for rhenium concentrate.[34]

Bibliography

  • Tacke, Ida, and D. Holde. 1921. Über Anhydride höherer aliphatischer Fettesäuren. Berlin, TeH., Diss., 1921. (On higher aliphatic fatty acid anhydrides )
  • Noddack, Walter, Otto Berg, and Ida Tacke. 1925. Zwei neue Elemente der Mangangruppe, Chemischer Teil. [Berlin: In Kommission bei W. de Gruyter]. (Two new elements of the manganese chemical group)
  • Noddack, Ida, and Walter Noddack. 1927. Das Rhenium. Ergebnisse Der Exakten Naturwissenschaften. 6. Bd. (1927) (Rhenium)
  • Noddack, Ida, and Walter Noddack. 1933. Das Rhenium. Leipzig: Leopold Foss. (Rhenium)
  • Noddack, Ida (1934). Über das Element 93. Angewandte Chemie. 47(37): 653-655. (On Element 93).
  • Noddack, Walter, and Ida Noddack. 1937. Aufgaben und Ziele der Geochemie. Freiburger wissenschaftliche Gesellschaft, Hft. 26. Freiburg im Breisgau: H. Speyer, H.F. Schulz. (Tasks and goals of Geochemistry)
  • Noddack, Ida, and Walter Noddack. 1939. Die Häufigkeiten der Schwermetalle in Meerestieren. Arkiv för zoologi, Bd. 32, A, Nr. 4. Stockholm: Almqvist & Wiksell. (The frequency of heavy metals in marine animals)
  • Noddack, Ida. 1942. Entwicklung und Aufbau der chemischen Wissenschaft. Freiburg i.Br: Schulz. (The development and structure of chemical science)

References

  1. Habashi, Fathi (1 March 2009). "Ida Noddack and the missing elements". Education in Chemistry. Vol. 46 no. 2. Royal Society of Chemistry. pp. 48–51. Retrieved 29 January 2018.
  2. "Tacke, Ida Eva". University of Alabama Astronomy Program. Retrieved 2013-03-11.
  3. Noddack was also awarded the German Chemical Society's prestigious Liebig Medal in 1931 along with her husband. In 1934, they received the Scheele Medal of the Swedish Chemical Society and in the same year they secured yet another German patent, for rhenium concentrate. Crawford, E. (May 20, 2002). The Nobel Population 1901-1950: A Census of the Nominations and Nominees for the Prizes in Physics and Chemistry. pp. 278, 279, 283, 284, 292, 293, 300, 301.
  4. Annette Lykknes, Donald L. Opitz, and Brigitte Van Tiggelen, eds., For Better or for Worse? Collaborative Couples in Science (n.p.: Springer Basel, 2012), 105.
  5. Lykknes, Opitz, and Van Tiggelen, For Better, 105
  6. Gildo Magalhäes Santos, "A tale of oblivion: Ida Noddack and the 'universal abundance' of matter", Notes and Records of the Royal Society of London 68 (2014): 374.
  7. Gregersen, Erik. "Ida Noddack". Encyclopædia Britannica.
  8. Annette Lykknes; Donald L. Opitz; Brigitte van Tiggelen (eds.). For better or for worse? : collaborative couples in the sciences (1st ed.). [Basel]: Birkhäuser. ISBN 978-3-0348-0285-7.
  9. Noddack, Ida (1934). Über das Element 93. Angewandte Chemie. 47(37): 653-655. (On Element 93).
  10. B. Fernandez and Georges Ripka, Unravelling the Mystery of the Atomic Nucleus: A Sixty Year Journey 1896-1956 (New York, NY: Springer, 2013), 352, Google Books.
  11. Miriam Grobman, "Ida and the Atom, 1934", Medium, last modified March 9, 2016, accessed May 15, 2018.
  12. FERMI, E. (1934). "Possible Production of Elements of Atomic Number Higher than 92". Nature. 133 (3372): 898–899. Bibcode:1934Natur.133..898F. doi:10.1038/133898a0.
  13. Noddack, Ida (September 1934). "On Element 93". Zeitschrift für Angewandte Chemie. 47 (37): 653. doi:10.1002/ange.19340473707. English Translation. Archived from the original on 2007-02-05.
  14. Joliot-Curie, Irène; Savić, Pavle (1938). "On the Nature of a Radioactive Element with 3.5-Hour Half-Life Produced in the Neutron Irradiation of Uranium". Comptes Rendus. 208 (906): 1643.
  15. Translation in American Journal of Physics, January 1964, p. 9-15O. Hahn; F. Strassmann (January 1939). "Concerning the Existence of Alkaline Earth Metals Resulting from Neutron Irradiation of Uranium". Die Naturwissenschaften. 27 (1): 11–15. Bibcode:1939NW.....27...11H. doi:10.1007/BF01488241. S2CID 5920336. Archived from the original (English Translation) on 2007-02-05.
  16. Bohr, N (1936). "Neutron capture and nuclear constitution". Nature. 137 (3461): 344. Bibcode:1936Natur.137..344B. doi:10.1038/137344a0. S2CID 4117020.
  17. Bohr N.; Kalckar F. (1937). "On the Transmutation of Atomic Nuclei by Impact of Material Particles. I. General theoretical remarks". Matematisk-Fysiske Meddelelser Kongelige Danske Videnskabernes Selskab. 14 (Nr. 10): 1.
  18. "Report Of The Third Washington Conference On Theoretical Physics". President's Papers/RG0002; Office of Public Relations. March 12, 1937. Archived from the original on May 2, 2007. Retrieved 2007-04-01.
  19. Lise Meitner, Otto Robert Frisch (Feb 11, 1939). "Disintegration of Uranium by Neutrons: a New Type of Nuclear Reaction". Nature. 143 (5218): 239–240. Bibcode:1969Natur.224..466M. doi:10.1038/224466a0. S2CID 4188874. Archived from the original on April 18, 2008.
  20. Otto Robert Frisch (Feb 18, 1939). "Physical Evidence for the Division of Heavy Nuclei under Neutron Bombardment". Nature. 143 (3616): 276. Bibcode:1939Natur.143..276F. doi:10.1038/143276a0. S2CID 4076376. Archived from the original on January 23, 2009.
  21. Niels Bohr (Feb 25, 1939). "Disintegration of Heavy Nuclei". Nature. 143 (3617): 330. Bibcode:1939Natur.143..330B. doi:10.1038/143330a0. S2CID 4090055. Archived from the original on 2005-03-24.
  22. Kenna, B. T.; Kuroda, P. K. (December 1961). "Isolation of naturally occurring technetium". Journal of Inorganic and Nuclear Chemistry. 23 (1–2): 142–144. doi:10.1016/0022-1902(61)80098-5.
  23. By reanalysing the original experimental conditions, we conclude that the detection limit for their observing the X-rays of Z = 43 can be 1000 times lower than the 10−9 detection limit for the element Z = 75. Pieter H. M. Van Assche (4 April 1988). "The ignored discovery of the element-Z=43". Nuclear Physics A. 480 (2): 205–214. Bibcode:1988NuPhA.480..205V. doi:10.1016/0375-9474(88)90393-4.
  24. "I simulated the X-ray spectra that would be expected for Van Assche's initial estimates of the Noddacks' residue compositions. ...Over the next couple of years, we refined our reconstruction of their analytical methods and performed more sophisticated simulations. The agreement between simulated and reported spectra improved further. " Armstrong, John T. (February 2003). "Technetium". Chemical & Engineering News. 81 (36): 110. doi:10.1021/cen-v081n036.p110.
  25. Günter Herrmann (11 December 1989). "Technetium or masurium — a comment on the history of element 43". Nuclear Physics A. 505 (2): 352–360. Bibcode:1989NuPhA.505..352H. doi:10.1016/0375-9474(89)90379-5.
  26. Habashi, F. (2005). Ida Noddack (1896-1978):Personal Recollections on the Occasion of 80th Anniversary of the Discovery of Rhenium. Québec City, Canada: Métallurgie Extractive Québec. p. 59. ISBN 978-2-922686-08-1.
  27. Abstract: A careful study of the history of the element 43 covering a period of 63 years since 1925 reveals that there is no reason for believing the Noddacks and Berg have discovered element 43.P. K. Kuroda (16 October 1989). "A Note on the Discovery of Technetium". Nuclear Physics A. 503 (1): 178–182. Bibcode:1989NuPhA.503..178K. doi:10.1016/0375-9474(89)90260-1.
  28. P. K. Kuroda (1982). The Origin of Chemical Elements and the Oklo Phenomenon. Berlin;New York:Springer-Verlag. ISBN 978-0-387-11679-2.
  29. Noddack, W.; Tacke, I.; Berg, O (1925). "Die Ekamangane". Naturwissenschaften. 13 (26): 567–574. Bibcode:1925NW.....13..567.. doi:10.1007/BF01558746. S2CID 32974087.
  30. ... P. H. Van Assche and J. T. Armstrong, cannot stand up to the well-documented assertion of the well-established physicist Paul K. Kuroda (1917 2001) in his paper, "A Note on the Discovery of Technetium" that the Noddacks did not discover technetium, then known as masurium. More about this matter can be found in Kuroda's book, The Origin of Chemical Elements and the Oklo Phenomenon, and the book Ida Noddack (1896 1978). Personal Recollections on the Occasion of 80th Anniversary of the Discovery of Rhenium recently published by the writer...Fathi Habashi
    • Since the publication in this Journal of my paper on the discovery of element 43 (1), I have received a few letters questioning the correctness of the next to last paragraph, in the section entitled Nemesis....
    I am deeply indebted to George B. Kauffman, Fathi Habashi, Gunter Herrmann, and Jean Pierre Adloff, who provided me with additional information and convinced me to better consider the published material on the so-called Noddacks' rehabilitation and to correct with this letter my gross mistake, for which I apologize. Roberto Zingales
    1. Zingales, R. J. Chem. Educ. 2005, 82, 221227
    Fathi Habashi; Roberto Zingales (February 2006). "Letters The History of Element 43--Technetium" (PDF). Journal of Chemical Education. 83 (2): 213. Bibcode:2006JChEd..83..213Z. doi:10.1021/ed083p213.2.
  31. Masataka Ogawa's discovery of nipponium was accepted once in the periodic table of chemical elements as the element 43, but disappeared later. However, nipponium clearly shows characteristics of rhenium (Z=75) by inspection of his papers from the modern chemical viewpoints...a record of X-ray spectrum of Ogawa's nipponium sample from thorianite was contained in a photographic plate reserved by his family. The spectrum was read and indicated the absence of the element 43 and the presence of the element 75H. K. Yoshihara (31 August 2004). "Discovery of a new element 'nipponium': re-evaluation of pioneering works of Masataka Ogawa and his son Eijiro Ogawa". Spectrochimica Acta Part B: Atomic Spectroscopy. 59 (8): 1305–1310. Bibcode:2004AcSpe..59.1305Y. doi:10.1016/j.sab.2003.12.027.
  32. In a recent evaluation of the discovery of "nipponium," supposed to be element 43 by Masataka Ogawa in 1908, and confirmed but not published by his son Eijiro in the 1940s, Kenji Yoshihara remeasured a photographic plate of an X-ray spectrum taken by Ogawa and found the spectral lines were those of rhenium. Thus actually, rhenium was discovered many years before Noddack, Tacke, and Berg's work. . H. Kenji Yoshihra; Teiji Kobayashi; Masanori Kaji (November 2005). "Ogawa Family and Their'Nipponium' Research: Successful Separation of the Element 75 before Its Discovery by Noddacks". Historia Scientiarum. 15 (2).
  33. Element 75 was isolated in 1908 by the Japanese chemist Masataka Ogawa and named nipponium. He inadequately assigned it as element 43 (technetium). From the modern chemical viewpoint it has to be considered to be element 75. Peter van der Krogt. "75 Rhenium". Elementymology & Elements Multidict. Retrieved 2007-04-03.
  34. Crawford, E. (May 20, 2002). The Nobel Population 1901-1950: A Census of the Nominations and Nominees for the Prizes in Physics and Chemistry. pp. 278, 279, 283, 284, 292, 293, 300, 301.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.