George de Hevesy

Hungarian–Swedish chemist (1885–1966)

Hevesy came from a family of wealthy industrialists in Budapest, the Hungarian capital. He was educated in Budapest and at the University of Freiburg where he obtained his doctorate in 1908. He then worked in Zurich, Karlsruhe, Manchester, and Copenhagen, before his appointment to the chair of physical chemistry in 1926 at Freiburg. In 1935 he left Germany for Denmark, fleeing from the Nazis who caught up with him once more in 1942, when he sought refuge in Sweden at the University of Stockholm.

In 1923 Hevesy discovered the new element hafnium in collaboration with Dirk Coster. His most important work, however, began in 1911 in the Manchester laboratory of Ernest Rutherford, where he worked on the separation of ‘radium D’ from a sample of lead. In fact radium D was a radioactive isotope of lead (lead–210) and could not be separated by chemical means. Hevesy was quick to see the significance of this and began exploring the use of radioactive isotopes as tracers. In 1913, with Friedrich Adolph Paneth, he used radioactive salts of lead and bismuth to determine their solubilities. In 1923 Hevesy made the first application of a radioactive tracer – Pb–212 – to a biological system. The Pb–212 was used to label a lead salt that plants took up in solution. At various time intervals plants were burned and the amount of lead taken up could be determined by simple measurements of the amount of radioactivity present. The drawback of this technique was the high toxicity of lead to most biological systems and it was only with the discovery of artificial radioactivity by Irène andFrédéric Joliot-Curie in 1934 that Hevesy's radioactive tracers developed into one of the most widely used and powerful techniques for the investigation of living and of complex systems. For his work in the development of radioactive tracers Hevesy was awarded the 1943 Nobel Prize for chemistry.

The Hungarian chemist George Charles de Hevesy (1885-1966) was a pioneer of isotope labeling and codiscoverer of the element hafnium.

George de Hevesy was born in Budapest on Aug. 1, 1885. He studied at Freiburg, Zurich, and Karlsruhe and in 1911 joined Ernest Rutherford at Manchester. His assignment there, to separate radium-D from lead, proved impossible, because radium-D, as was later demonstrated, actually comprises isotopes. Yet the 2 years were not wasted, for Hevesy gained valuable technical experience in the new field of radiochemistry. In 1913 he left for Vienna to join F. A. Paneth, whose experience with radium-D had been similar. They studied the exchange between radioactive and nonradioactive lead atoms, showing that, for all ordinary processes, the chemical and physical behavior of these atoms was identical. Also, by using radioactive (labeled) samples to determine the solubilities of various lead salts, they introduced the technique of radioactive tracers.

In 1920 Hevesy moved to Niels Bohr's institute at Copenhagen, where his attention was directed to the possibility of separating isotopes. In 1922 Hevesy, working with J. N. BrÓnsted, effected a partial separation of the isotopes of mercury by repeated fractional distillation; he had similar success with chlorine and potassium. Hevesy then joined D. Coster in a search for missing element number 72. In examining zirconium minerals they found six unaccountable lines in x-ray spectra and attributed them to the new element, which they named hafnium. Hevesy began using radioactive isotopes as tracers: he studied the absorption of lead by the bean plant (1923) and the distribution and elimination of bismuth injected into rabbits (1924). These were the earliest applications of tracer techniques to biological problems.

In 1926 Hevesy moved to the University of Freiburg, where he developed the use of x-ray fluorescence for mineral analyses and began tracer experiments with stable isotopes. With some deuterium-enriched ("heavy") water, received as a gift from its discoverer, H. Urey, Hevesy studied water exchange between a goldfish and its surroundings, and within the human body. He showed that the human body retains water molecules much longer.

Political pressure compelled Hevesy to move again in 1934, and he returned to Copenhagen. There biology dominated his research, as the recently produced radiophosphorus had become available for studies on metabolism. He examined the rates of exchange of phosphorus in plants, yeast cells, and animal organs, as well as the excretion of phosphate and its exchange between plasma and corpuscles, and the effects of x-rays on the metabolism of malignant tumors.

Aware of the growing hostility of the Nazis, Hevesy escaped to Stockholm in 1944. There he continued his biological tracer work with much success, including studies on the formation and fate of red corpuscles in the blood. He was awarded the Nobel Prize in chemistry in 1944 and for another 20 years made further explorations in the field that he had pioneered. In 1959 he received the Atoms for Peace Prize. Hevesy died in Freiburg on July 5, 1966.

Further Reading

An extensive sketch of Hevesy's life is in The Royal Society, London, Biographical Memoirs of Fellows of the Royal Society, vol. 13 (1967). Biographical information is also in Eduard Farber, Nobel Prize Winners in Chemistry, 1901-1961 (1953; rev. ed. 1963), and Nobel Foundation, Chemistry: Including Presentation Speeches and Laureates' Biographies, vol. 3 (1964). For background see Aaron J. Ihde, The Development of Modern Chemistry (1964).

Additional Sources

Frontiers in nuclear medicine, Berlin; New York: Springer, 1980.

Levi, Hilde, George de Hevesy: life and work: a biography, Bristol; Boston: A. Hilger, 1985.

The native form of this personal name is Hevesy György. This article uses the Western name order.

György Hevesy
Born	1 August 1885(1885-08-01) Budapest, Hungary
Died	5 July 1966 (aged 80) Freiburg, Germany
Citizenship	Germany
Nationality	Hungary
Fields	Chemistry
Institutions	University of Budapest Niels Bohr Institute ETH Zürich University of Freiburg University of Manchester Stefan Meyer Institute for Subatomic Physics
Alma mater	University of Freiburg
Doctoral advisor	Georg Franz Julius Meyer
Doctoral students	Max Pahl
Known for	Hafnium
Notable awards	Nobel Prize for Chemistry (1943)

George Charles de Hevesy, Georg Karl von Hevesy, (1 August 1885 – 5 July 1966) was a Hungarian radiochemist and Nobel laureate, recognized in 1943 for his key role in the development of radioactive tracers to study chemical processes such as in the metabolism of animals.

Contents 1 Biography 1.1 Early years 1.2 Research 2 World War II and beyond 2.1 Personal life 3 See also 4 References 5 Further reading 6 External links

Biography

Early years

Hevesy György was born in Budapest, Hungary of Hungarian Jewish decent, the fifth of eight children from his wealthy parents Bischitz Louis Schossberger and Eugenia (Jenny). George grew up in Budapest and graduated high school in 1903 from Piarista Gimnázium. The family's name in the 1904 was Hevesy-Bischitzre, and Hevesy later changed his own.

De Hevesy began his studies in chemistry at the University of Budapest for one year, and at the Technical University of Berlin for several months, but changed to the University of Freiburg. There he came in contact with Ludwig Gattermann. In 1906 he started his Ph.D. thesis with Georg Franz Julius Meyer, acquiring his doctorate in physics in 1908. In 1908 Hevesy got a position at the ETH.

Research

When Richard Lorenz left for the University of Frankfurt and Richard Willstätter tried to convince him to stay in Zurich he decided to go to the University of Karlsruhe to work with Carl Bosch. To learn new methods, de Hevesy joined Rutherford's laboratory at the University of Manchester in 1911 where he met and became friends with Niels Bohr.

In 1923 de Hevesy co-discovered hafnium (₇₂Hf) (Latin Hafnia for "Copenhagen", the home town of Niels Bohr), with Dirk Coster. Mendeleev's periodic table in 1869 put the chemical elements into a logical system, however there was missing a chemical element with 72 protons. On the basis of Bohr's atomic model Hevesy came to the conclusion that there must be a chemical element that goes there. The mineralogical museum of Norway and Greenland in Copenhagen furnished the material for the research. Characteristic X-ray spectra recordings made in the sample indicated that a new element was present. This earned him the 1943 Nobel Prize in Chemistry.

Hevesy was offered a job from the University of Freiburg chemistry post accepted. Supported financially by the Rockefeller Foundation, he had a very productive year. He developed the X-ray florescence analytical method, and discovered that the Samarium alpha-ray. It was here he began the use of radioactive isotopes in studying the metabolic processes of plants and animals, by tracing chemicals in the body by replacing stable isotopes with adding small quantities of the radioactive isotopes. Modern medical science owes a lot to his development of this method.

World War II and beyond

When Germany invaded Denmark in World War II, de Hevesy dissolved the gold Nobel Prizes of Max von Laue and James Franck with aqua regia to prevent the Nazis from stealing them. He placed the resulting solution on a shelf in his laboratory at the Niels Bohr Institute. After the war, he returned to find the solution undisturbed and precipitated the gold out of the acid. The Nobel Society then recast the Nobel Prizes using the original gold.^[1][2]

In 1943, Copenhagen was no longer seen as safe for a Jewish scientist, and de Hevesy fled to Sweden, where he worked at the Stockholm University College until 1961. Interestingly enough, in Stockholm, de Hevesy was received at the department of German-Swedish professor and Nobel Prize winner Hans von Euler-Chelpin, who remained strongly pro-German throughout war. Despite this, de Hevesy and von Euler-Chelpin collaborated on many scientific papers during and after the war.

During his time in Stockholm, de Hevesy received the Nobel Prize in chemistry. In 1959 he received the Atoms for Peace Award for his peaceful use of radioactive isotopes. He later was inducted as a member of the Royal Society and received the Copley Medal, of which he was particularly proud. The 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 received Nobel chemistry prizes, but only ten foreign members of the Royal Society and two (Bohr and Hevesy) received a medal-Copley." George de Hevesy was elected a foreign member of the Royal Swedish Academy of Sciences in 1942, and his status was later changed to Swedish member. In 1949 he was elected Franqui Professor in the University of Ghent. He received the Atoms for Peace Award in 1958.

George de Hevesy's grave in Budapest. Cemetery Kerepesi: 27 Hungarian Academy of Sciences.

de Hevesy died in 1966 at the age of eighty and was buried in the Kerepesi Cemetery in Budapest, Hungary.^[3]. He had made a total of 397 scientific publications. In 2001 At his family's request, his ashes were interned at his birthplace in Budapest on April 19, 2001.

Personal life

George de Hevesy married Pia Riis in 1924. They had one son and three daughters.

See also

• Johanna Bischitz de Heves

References

1. ^ Birgitta Lemmel (2006). "The Nobel Prize Medals and the Medal for the Prize in Economics". The Nobel Foundation. http://nobelprize.org/nobel_prizes/medals/. 
2. ^ de Hevesy, George, Adventures in Radioisotope Research, Vol. 1, p. 27, Pergamon, New York, 1962
3. ^ See this site.

Further reading

• 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, PMID 797570 
• Ostrowski, W. (1968), "George Hevesy inventor of isotope methods in biochemical studies", Postepy Biochem. 14 (1): 149–53, PMID 4870858 
• Dal Santo, G. (1966), "Professor George C. De Hevesy. In reverent memory", Acta Isotopica 6 (1): 5–8, 1966 Sep 30, PMID 4865432 
• "George De Hevesy", Triangle; The Sandoz Journal of Medical Science 91: 239–40, 1964, 1964 Jul, PMID 14184278 
• Cockcroft, John D. (1967). "George de Hevesy. 1885-1966". Biographical Memoirs of Fellows of the Royal Society 13 (42): 125–166. doi:10.1098/rsbm.1967.0007. http://links.jstor.org/sici?sici=0080-4606%28196711%2913%3C125%3AGDH1%3E2.0.CO%3B2-R. 

External links

• George de Hevesy – Biography
• Annotated bibliography for George de Hevesy from the Alsos Digital Library for Nuclear Issues
• [1]Weintraub, B. (2005) George de Hevesy:Hafnium and Radioactive Traces; Chemistry in Israel, Bull. Isr. Chem. Soc., Issue 18, April 2005. p 41-43.

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v • d • e Hungarian or Hungarian-Born Nobel Laureates       Lénárd Fülöp (1905) · Bárány Róbert (1914) · Zsigmondy Richárd (1925) · Szent-Györgyi Albert (1937) · Hevesy György (1943) · Békésy György (1961) · Wigner Jenő (1963) · Gábor Dénes (1971) · Polányi János (1986) · Elie Wiesel (1986) · Harsányi János (1994) · Oláh György (1994) · Kertész Imre (2002) · Avram Hershko (2004) ·

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