List of chemical elements naming controversies
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The currently accepted names and symbols of the chemical elements are determined by the International Union of Pure and Applied Chemistry (IUPAC), usually following recommendations by the recognized discoverers of each element. However the names of several elements have been the subject of controversies until IUPAC established an official name. In most cases the controversy was due to a priority dispute as to who first found conclusive evidence for the existence of an element, or as to what evidence was in fact conclusive. This article provides a brief history of these controversies, in order of the atomic number of the elements concerned.
Element 23
Vanadium (named after Vanadis, another name for Freyja, the Scandinavian goddess of fertility) was originally discovered by Andrés Manuel del Río (a Spanish-born Mexican mineralogist) in Mexico City in 1801. He discovered the element after being sent a sample of "brown lead" ore (plomo pardo de Zimapán, now named vanadinite). Through experimentation, he found it to form salts with a wide variety of colors, so he named the element panchromium (Greek: all colors). He later renamed this substance erythronium, since most of the salts turned red when heated. The French chemist Hippolyte Victor Collet-Descotils incorrectly declared that del Río's new element was only impure chromium. Del Río thought himself to be mistaken and accepted the statement of the French chemist that was also backed by del Río's friend Alexander von Humboldt.[1]
In 1831, Sefström of Sweden rediscovered vanadium in a new oxide he found while working with some iron ores. He chose to call the element vanadium after the Old Norse Vanadís, another name for the Norse Vanr goddess Freyja, whose facets include connections to beauty and fertility, because of the many beautifully colored chemical compounds it produces. Later that same year Friedrich Wöhler confirmed del Río's earlier work.[2] Later, George William Featherstonhaugh, one of the first US geologists, suggested that the element should be named "rionium" after del Río, but this never happened.
Elements 41 and 74
Charles Hatchett named element 41 columbium in 1801[3] (Cb),[4] but after the publication of the identity of columbium with tantalum by William Hyde Wollaston in 1802 the claims of discovery of Hattchet were refused.[5] In 1846 Heinrich Rose discovered that tantalite contained an element similar to tantalum and named it niobium.[6][7]
IUPAC officially adopted niobium in 1950 after 100 years of controversy.[8] This was a compromise of sorts; the IUPAC accepted tungsten instead of wolfram (in deference to North American usage)[8][9][10] and niobium instead of columbium (in deference to European usage).[8][10]
Elements 70 and 71
Gadolinite, a mineral (from Ytterby, a village in Sweden), consists of several compounds (oxides or earths): yttria, erbia (sub-component as ytterbia) and terbia.
In 1878 Jean Charles Galissard de Marignac assumed that ytterbia consisted of a new element he called ytterbium (but actually there were two new elements). In 1907 Georges Urbain isolated element 70 and element 71 from ytterbia. He called element 70 neoytterbia ("new ytterbium") and called element 71 lutecia. At about the same time, Carl Auer von Welsbach also independently isolated these and proposed the names aldebaranium (Ad), after the star Aldebaran (in the constellation of Taurus), for element 70 (ytterbium), and cassiopeium (Cp), after the constellation Cassiopeia, for element 71 (lutetium), but both proposals were rejected.
Neoytterbia (element 70) was eventually reverted to ytterbium (following Marignac) and in 1949 the spelling of lutecia (element 71) was changed to lutetium.
(Other elements, yttrium (element 39) and gadolinium (element 64), were also discovered in gadolinite and its components, but there was no controversy about their names.)
Elements 103–109
At the time of their discovery, there was an element naming controversy as to what (particularly) the elements from 103 to 105 were to be called. At last, a committee of the International Union of Pure and Applied Chemistry (IUPAC) resolved the dispute and adopted one name for each element. They also adopted a temporary systematic element name.
Element 103
IUPAC ratified the name lawrencium (Lr) in honor of Ernest Lawrence during a meeting in Geneva; the name was preferred by the American Chemical Society.
Element 104
The Joint Institute for Nuclear Research in Dubna (then U.S.S.R., today Russia) named element 104 kurchatovium (Ku) in honor of Igor Kurchatov, father of the Soviet atomic bomb. But the University of California, Berkeley, U.S.A. named element 104 rutherfordium (Rf) in honor of Ernest Rutherford. In 1997 a committee of IUPAC recommended that element 104 be named rutherfordium.
Element 105
The Joint Institute for Nuclear Research in Dubna proposed naming element 105 nielsbohrium (Ns) after Niels Bohr, while the University of California, Berkeley suggested the name hahnium (Ha) in honor of Otto Hahn. IUPAC recommended that element 105 be named dubnium, after Dubna.
Element 106
The element was discovered almost simultaneously by two different laboratories. In June 1974, a Soviet team led by G. N. Flyorov at the Joint Institute for Nuclear Research at Dubna reported producing the isotope 259106, and in September 1974, an American research team led by Albert Ghiorso at the Lawrence Radiation Laboratory at the University of California, Berkeley reported creating the isotope 263106. Because their work was independently confirmed first, the Americans suggested the name seaborgium (Sg) in honor of Glenn T. Seaborg, an American chemist. This name was extremely controversial because Seaborg was still alive.
An international committee decided in 1992 that the Berkeley and Dubna laboratories should share credit for the discovery. An element naming controversy erupted and as a result IUPAC adopted unnilhexium (Unh) as a temporary, systematic element name.
In 1994 a committee of IUPAC adopted a rule that no element can be named after a living person. This ruling was fiercely objected to by the American Chemical Society.
Critics pointed out that a precedent had been set in the naming of einsteinium (Es), element 99, during Albert Einstein's life, although it was not publicly announced until after his death. In 1997, as part of a compromise involving elements 104 to 108, the name seaborgium for element 106 was recognized internationally.
Element 107
Some suggested the name nielsbohrium (Ns), in honor of Niels Bohr (this was separate from the proposal of the same name for element 105). IUPAC adopted unnilseptium (Uns) as a temporary systematic element name. In 1994 a committee of IUPAC recommended that element 107 be named bohrium (Bh), also in honor of Niels Bohr but using his surname only. While this conforms to the names of other elements honoring individuals where only the surname is taken, it was opposed by many who were concerned that it could be confused with boron. Despite this, the name bohrium for element 107 was recognized internationally in 1997.
Element 108
IUPAC adopted unniloctium (Uno) as a temporary, systematic element name. In 1997 a committee of IUPAC recommended that element 108 be named hassium (Hs), in honor of the German state of Hesse (or Hassia in Latin), in which the city of Darmstadt is located, which is home to the GSI Helmholtz Centre for Heavy Ion Research where several new elements were discovered or confirmed. This name was accepted internationally.
Element 109
IUPAC adopted unnilennium (Une) as a temporary, systematic element name. While meitnerium was discussed in the naming controversy, it was the only proposal and thus never disputed. In 1997 a committee of IUPAC adopted the name meitnerium in honor of Lise Meitner (Mt).
Post-controversial namings
Elements 110 (Ds, darmstadtium), 111 (Rg, roentgenium), 112 (Cn, copernicium), 114 (Fl, flerovium), and 116 (Lv, livermorium) were named after the end of the controversy.
See also
- List of chemical element name etymologies
- Symbol (chemical element)#Symbols not currently used
- IUPAC/IUPAP Joint Working Party reports on claims of new transuranium elements.
References
Notations
- Rayner-canham, Geoff; Zheng, Zheng (2007). "Naming elements after scientists: an account of a controversy". Foundations of Chemistry 10 (1): 13. doi:10.1007/s10698-007-9042-1.
Footnotes
- ↑ Cintas, Pedro (2004). "The Road to Chemical Names and Eponyms: Discovery, Priority, and Credit". Angewandte Chemie International Edition 43 (44): 5888–5894. doi:10.1002/anie.200330074. PMID 15376297.
- ↑ Sefström, Nils Gabriel (1831). "Ueber das Vanadin, ein neues Metall, gefunden im Stangeneisen von Eckersholm, einer Eisenhütte, die ihr Erz von Taberg in Småland bezieht". Annalen der Physik und Chemie 97 (1): 43–49. Bibcode:1831AnP....97...43S. doi:10.1002/andp.18310970103.
- ↑ Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. p. 976. ISBN 0-08-037941-9.
- ↑ Hatchett, Charles (1802). "Eigenschaften und chemisches Verhalten des von Charlesw Hatchett entdeckten neuen Metalls, Columbium". Annalen der Physik (in German) 11 (5): 120–122. Bibcode:1802AnP....11..120H. doi:10.1002/andp.18020110507.
- ↑ Wollaston, William Hyde (1809). "On the Identity of Columbium and Tantalum". Philosophical Transactions of the Royal Society of London 99 (0): 246–252. doi:10.1098/rstl.1809.0017. JSTOR 107264.
- ↑ Rose, Heinrich (1844). "Ueber die Zusammensetzung der Tantalite und ein im Tantalite von Baiern enthaltenes neues Metall". Annalen der Physik (in German) 139 (10): 317–341. Bibcode:1844AnP...139..317R. doi:10.1002/andp.18441391006.
- ↑ Rose, Heinrich (1847). "Ueber die Säure im Columbit von Nordamérika". Annalen der Physik (in German) 146 (4): 572–577. Bibcode:1847AnP...146..572R. doi:10.1002/andp.18471460410.
- 1 2 3 Rayner-Canham, Geoff; Zheng, Zheng (2008). "Naming elements after scientists: an account of a controversy". Foundations of Chemistry 10 (1): 13–18. doi:10.1007/s10698-007-9042-1.
- ↑ Patel, Zh.; Khul'ka K. (2001). "Niobium for Steelmaking". Metallurgist 45 (11–12): 477–480. doi:10.1023/A:1014897029026.
- 1 2 Norman N., Greenwood (2003). "Vanadium to dubnium: from confusion through clarity to complexity". Catalysis Today 78 (1–4): 5–11. doi:10.1016/S0920-5861(02)00318-8.
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