Julius Lothar Meyer
Julius Lothar Meyer (19 August 1830 – 11 April 1895) was a German chemist. He was one of the pioneers in developing the first periodic table of chemical elements. Both Mendeleev and Meyer worked with Robert Bunsen. He never used his first given name, and was known throughout his life simply as Lothar Meyer.
Meyer in 1883
|Born||19 August 1830|
|Died||11 April 1895 (aged 65)|
|Alma mater||University of Würzburg, University of Breslau|
|Known for||Periodic table of chemical elements|
|Awards||Davy Medal (1882)|
|Institutions||University of Tübingen|
Lothar Meyer was born in Varel, Germany (then part of the Duchy of Oldenburg). He was the son of Friedrich August Meyer, a physician, and Anna Biermann. After attending the Altes Gymnasium in Oldenburg, he studied medicine at the University of Zurich in 1851. Two years later, he studied at the University of Würzburg, where he studied pathology, as a student of Rudolf Virchow. At Zurich, he had studied under Carl Ludwig, which had prompted him to devote his attention to physiological chemistry. After graduating as a Doctor of Medicine from Würzburg in 1854, he went to the University of Heidelberg, where Robert Bunsen held the chair of chemistry. In 1858, he received a Ph.D. in chemistry from the University of Breslau with a thesis on the effects of carbon monoxide on the blood. With this interest in the physiology of respiration, he had recognized that oxygen combines with the hemoglobin in blood.
Influenced by the mathematical teaching of Gustav Kirchhoff, he took up the study of mathematical physics at the University of Königsberg under Franz Ernst Neumann, and in 1859, after having received his habilitation (certification for university teaching), he became Privatdozent in physics and chemistry at the University of Breslau. In 1866, Meyer accepted a post at the Eberswalde Forestry Academy at Neustadt-Eberswalde but two years later was appointed to a professorship at the Karlsruhe Polytechnic.
In 1872, Meyer was the first to suggest that the six carbon atoms in the benzene ring (that had been proposed a few years earlier by August Kekulé) were interconnected by single bonds only, the fourth valence of each carbon atom being directed toward the interior of the ring.
During the Franco-German campaign, the Polytechnic was used as a hospital, and Meyer took an active role in the care of the wounded. In 1876, Meyer became Professor of Chemistry at the University of Tübingen, where he served until his death.
Meyer is best known for his part in the periodic classification of the elements. He noted, as J. A. R. Newlands did in England, if each element is arranged in the order of their atomic weights, they fall into groups of similar chemical and physical properties repeated at periodic intervals. According to him, if the atomic weights were plotted as ordinates and the atomic volumes as abscissae—the curve obtained a series of maxima and minima—the most electro-positive elements appearing at the peaks of the curve in the order of their atomic weights.
His book, Die modernen Theorien der Chemie, which he began writing in Breslau in 1862 and which was published two years later, contained an early version of the periodic table containing 28 elements, classified elements into six families by their valence—for the first time, elements had been grouped according to their valence. Works on organizing the elements by atomic weight, until then had been stymied by the widespread use of equivalent weights for the elements, rather than atomic weights.
He published articles about classification table of the elements in horizontal form (1864) and vertical form (1870), in which the series of periods are properly ended by an element of the alkaline earth metal group.
In 1869, Dmitri Mendeleev published a periodic table of all elements known at that time (he later predicted several new elements to complete the table, and corrected some atomic weights). A few months later, Meyer published a paper that included a revised version of his 1864 table that now included virtually all of the known elements, which was similar to the table published by Mendeleev. Meyer had developed his fuller periodic table independently, but he acknowledged Mendeleev's priority. Included in Meyer's paper was a line chart of atomic volumes as a function of atomic weights, showing graphically the periodicity of the elements. Like Mendeleev, he also included predictions of future elements, but unlike Mendeleev did not emphasize these predictions nor suggest details of the physical and chemical properties of the future elements.
The newly discovered mineral lotharmeyerite, Ca(Zn,Mn3+)2(AsO4)2•2(H2O,OH), was named in recognition of Meyer's work on the Periodic Law in 1983. The type locality is the Ojuela mine, Mapimí, Durango, Mexico. Four closely related minerals have been described since 1983: ferrilotharmeyerite, Ca(Fe3+,Zn)2(AsO4)2•2(OH,H2O) (1992); cobaltlotharmeyerite, Ca(Co,Fe3+,Ni)2(AsO4)2•2(H2O,OH) (1997); nickellotharmeyerite, Ca(Ni,Fe3+,Co)2(AsO4)2•2(H2O,OH) (1999); and manganlotharmeyerite, CaMn3+2(AsO4)2(OH)2 (2002).
Meyer's table with vertical display of periods in 1870Edit
Meyer married Johanna Volkmann in 1866.
- Sergei Vinogradskii and the Cycle of Life: From the Thermodynamics of Life ..., Lloyd Ackert
- The Disappearing Spoon...and other true tales from the Periodic Table, Sam Kean
- This article incorporates text from a publication now in the public domain: Chisholm, Hugh, ed. (1911). "Meyer, Julius Lothar". Encyclopædia Britannica. 18 (11th ed.). Cambridge University Press. pp. 348–349.
- Meyer, Julius Lothar; Die modernen Theorien der Chemie (1864); table on page 137, https://reader.digitale-sammlungen.de/de/fs1/object/goToPage/bsb10073411.html?pageNo=147
- Alan J. Rocke (1984). Chemical Atomism in the Nineteenth Century: From Dalton to Cannizzaro. Ohio State University Press.
- Makeyev A.K. (2013). "Julius Lothar Meyer was first to build the periodic table of elements". European Applied Sciences. 4 (2): 49–61. Archived from the original on 15 July 2013.
- Eric Scerri (2006). The Periodic Table: Its Story and Its Significance. Oxford University Press.
- Lotharmeyerite. https://www.mindat.org/min-2439.html, accessed 6/15/2018.
- Ferrilotharmeyerite. https://www.mindat.org/min-1495.html, accessed 6/15/2018.
- Cobaltlotharmeyerite. https://www.mindat.org/min-6885.html, accessed 6/15/2018.
- Nickellotharmeyerite. https://www.mindat.org/min-11004.html, accessed 6/15/2018.
- Manganlotharmeyerite. https://www.mindat.org/min-11206.html, accessed 6/15/2018.
- Krätz, Otto (1994), "Meyer, Lothar", Neue Deutsche Biographie (NDB) (in German), 17, Berlin: Duncker & Humblot, pp. 304–306; (full text online)
- Chisholm, Hugh, ed. (1911). Encyclopædia Britannica (11th ed.). Cambridge University Press. .
- Seubert, Karl (1918). "Nekrolog: Lothar Meyer". Berichte der Deutschen Chemischen Gesellschaft. 28 (4): 1109–1146. doi:10.1002/cber.18950280498.
- Harald Kluge and Ingrid Kaestner, Ein Wegbereiter der physikalischen Chemie im 19. Jahrhundert, Julius Lothar Meyer (1830–1895) (Aachen: Shaker-Verlag, 2014).
- Otto Kraetz, "Lothar Meyer," Neue Deutsche Biographie, 17 (1994), 304–6.
|Wikimedia Commons has media related to Lothar Meyer.|
- Works by or about Julius Lothar Meyer at Internet Archive
- Periodic table according to Lothar Meyer (1870)
- Video of a talk by Michael Gordin titled "Periodicity, Priority, Pedagogy: Mendeleev and Lothar Meyer"
- The Internet Database of Periodic Tables. Chemogenesis web book.
- . Encyclopedia Americana. 1920.
- Eric Scerri's website on the periodic table