Hevesy György was born inBudapest,Hungary, to a wealthy and ennobled family ofHungarian-Jewish descent,[7] the fifth of eight children to his parents Lajos Bischitz and Baroness Eugénia (Jenny) Schossberger (ennobled as "De Tornya"). Grandparents from both sides of the family had provided the presidents of the Jewish community ofPest.[7] His parents converted toRoman Catholicism.[8] George grew up in Budapest and graduated high school in 1903 fromPiarist Gimnázium.[9] The family's name in 1904 was Hevesy-Bischitz, and Hevesy later changed his own.
In 1922, de Hevesy co-discovered (withDirk Coster) the elementhafnium (72Hf) (LatinHafnia for "Copenhagen", the home town ofNiels Bohr).Mendeleev's 1869periodic table arranged the chemical elements into a logical system, but a chemical element with 72 protons was missing. Hevesy determined to look for that element on the basis of Bohr's atomic model. The mineralogical museum of Norway and Greenland in Copenhagen furnished the material for the research. CharacteristicX-ray spectra recordings made of the sample indicated that a new element was present. The accepted account has been disputed by Mansel Davies andEric Scerri who attribute the prediction that element 72 would be atransition element to the chemist Charles Bury.[citation needed]
Supported financially by theRockefeller Foundation, Hevesy had a very productive year. He developed theX-ray fluorescence analytical method, and discovered thesamarium alpha-ray. It was here he began the use ofradioactive isotopes in studying the metabolic processes of plants and animals, by tracing chemicals in the body by replacing part of stable isotopes with small quantities of the radioactive isotopes. In 1923, Hevesy published the first study on the use of the naturally radioactive212Pb as radioactive tracer to follow the absorption andtranslocation in the roots, stems and leaves ofVicia faba, also known as the broad bean.[11][12] Later, in 1943, the work on radioactive tracing would earn Hevesy theNobel Prize in Chemistry.[13]
In 1924, Hevesy returned to Freiburg as Professor of Physical Chemistry. In 1930, he went toCornell University, Ithaca as Baker Lecturer. In 1934, after the Nazis came to power in Germany, he returned to Niels Bohr's Institute at the University of Copenhagen. In 1936, he inventedNeutron Activation Analysis. In 1943 he fled to Stockholm (Sweden being neutral during the war), where was he an associate of the Institute of Research in Organic Chemistry. In 1949 he was elected Franqui Professor in theUniversity of Ghent. In his retirement, he remained an active scientific associate of theStockholm University.
Stolpersteine memorials for Georg and his wife Pia de Hevesy in Freiburg
Prior to the onset of World War II,Max von Laue andJames Franck had sent their goldNobel Prize medals toDenmark to keep them from being confiscated by the Nazis. After theNazi invasion of Denmark this placed them in danger; it was illegal at the time to send gold out of Germany, and were it discovered that Laue and Franck had done so, they could have faced prosecution. To prevent this, de Hevesy concealed the medals by dissolving them inaqua regia and placing the resulting solution on a shelf in his laboratory at theNiels Bohr Institute in Copenhagen. After the war, he returned to find the solution undisturbed and precipitated the gold out of the acid. The Nobel Society then recast the medals using the recovered gold and returned them to the two laureates.[14][15]
By 1943, Copenhagen was no longer safe for a Jewish scientist and de Hevesy fled to Sweden, where he worked at theStockholm University until 1961. In Stockholm, de Hevesy was received at the department of chemistry by the German-born Swedish professor and Nobel Prize winnerHans von Euler-Chelpin, who remained strongly pro-Germany throughout the war. Despite this, de Hevesy and von Euler-Chelpin collaborated on many scientific papers during and after the war.
While in Stockholm, de Hevesy received the Nobel Prize in chemistry. He was later inducted into theRoyal Swedish Academy of Sciences and received theCopley Medal, of which he was particularly proud. De Hevesy stated: "The public thinks the Nobel Prize in chemistry for the highest honor that a scientist can receive, but it is not so. Forty or fifty have received Nobel chemistry prizes, but there are only ten foreign members of the Royal Swedish Academy, and only two have received a Copley." (Bohr was the other one.) He received theAtoms for Peace Award in 1958 for his peaceful use ofradioactive isotopes.
George de Hevesy's grave in Budapest. Cemetery Kerepesi: 27 Hungarian Academy of Sciences.
De Hevesy married Pia Riis in 1924. They had one son and three daughters together, one of whom (Eugenie) married a grandson of the Swedish Nobel laureateSvante Arrhenius.[16] De Hevesy died in 1966 at the age of eighty and was buried in Freiburg. In 2000, his body was moved to theKerepesi Cemetery in Budapest, Hungary. He had published a total of 397 scientific documents, one of which was the Becquerel-Curie Memorial Lecture, in which he had reminisced about the careers of pioneers of radiochemistry.[17] At his family's request, his ashes were interred at his birthplace in Budapest on 19 April 2001.
^Levi, H. (1976). "George von Hevesy memorial lecture. George Hevesy and his concept of radioactive indicators--in retrospect".European Journal of Nuclear Medicine.1 (1):3–10.doi:10.1007/BF00253259.PMID797570.S2CID6640231.
^Ostrowski, W. (1968). "George Hevesy inventor of isotope methods in biochemical studies".Postepy Biochemii.14 (1):149–153.PMID4870858.
^Dal Santo, G. (1966). "Professor George C. De Hevesy. In reverent memory".Acta Isotopica.6 (1):5–8.PMID4865432.
^"George De Hevesy".Triangle; the Sandoz Journal of Medical Science.91:239–240. 1964.PMID14184278.
