Yevgeny Zavoisky

Yevgeny Konstantinovich Zavoisky (Russian: Евгений Константинович Завойский; September 28, 1907 – October 9, 1976) was a Soviet physicist known for discovery of electron paramagnetic resonance in 1944.[1][2] He likely observed nuclear magnetic resonance in 1941, well before Felix Bloch and Edward Mills Purcell, but dismissed the results as not reproducible.[3][4] Zavoisky is also credited with design of luminescence camera for detection of nuclear processes in 1952 and discovery of magneto-acoustic resonance in plasma in 1958.

Yevgeny Zavoisky
BornSeptember 28 [O.S. September 15] 1907
Died9 October 1976(1976-10-09) (aged 69)
Alma materKazan University
Known forDiscovery of electron paramagnetic resonance (1944)
AwardsStalin Prize (1949), Lenin Prize (1957), International EPR Society Prize (1977, posthumously)
Scientific career
FieldsSpectroscopy
InstitutionsKazan University, Arzamas-16, Institute of Atomic Energy
Signature

Early years

Zavoisky was born in 1907 in Mogilyov-Podolsk, a town in the south of Russian Empire (now in Vinnytsia oblast, Ukraine). His father Konstantin Ivanovich was a military doctor and mother Elizaveta Nikolaevna was trained as a teacher. In 1910, Zavoisky family moved to Kazan – a major Russian university city – for the sake of better education and well-being of their five children. There, Konstantin Ivanovich obtained a respectable job and a large apartment, which he equipped with equipment and books for home experiments with his children. Yevgeny, in particular, was keen to electromagnetism.[5][6]

The October revolution of 1917 brought difficult times. Konstantin Ivanovich died in 1919 from exhaustion, and the family moved to a small rural town to survive the hunger period. They returned to Kazan in 1925. In 1926, Yevgeny entered the faculty of physics at Kazan University. By that time, he was already an experienced amateur engineer who had assembled his own radio receivers and had numerous ideas of new inventions and measurements.[5] Zavoisky established himself as a talented student and researcher. He was sent to Saint Petersburg to continue his studies and after returning to Kazan had worked in the laboratory of oscillations at Kazan University. After defending his PhD in 1933, he became the laboratory head.[6] His research directions included generation of ultrashort waves; study of their physical and chemical effects on matter, including the effect on seed germination; and investigation of superregenerative effect. The seed germination topic was a reflection of that difficult period when scientists were required to try helping the Russian economy, which was recovering from the years of wars.[7]

Work on resonance phenomena

Zavoisky started systematic studies on interaction of electromagnetic waves with matter in 1933. He formed a group of talented experimentalists and theorists of various background, which included Boris Kozyrev, A. V. Nesmelov and later Semen Altshuler. He also visited several laboratories in major Russian cities and found that the experimental techniques in this research field were undeveloped. He was particularly dissatisfied with poor detection sensitivity and spent much effort on improving it using better detectors and electronic circuitry.[8]

Zavoisky was much interested in the pioneering results obtained by Isidor Isaac Rabi in 1938 on interaction of molecular beams with electromagnetic waves in a static magnetic field, that is nuclear magnetic resonance (NMR).[9] Eight years later, in 1946, Felix Bloch and Edward Mills Purcell refined the technique for use on liquids and solids, for which they shared the Nobel Prize in physics in 1952.[10] Zavoisky too tried to detect NMR in solids and liquids around 1940–1941. He had a sensitive enough detection system and managed to obtain the resonance signals. However, the strict requirement for the spatial homogeneity of the magnetic field were likely not met.[3] The signals were unstable and poorly reproducible and thus were discarded. The work was interrupted by World War II and had not been resumed.[6][11]

Instead, starting from 1943, Zavoisky focused on electron paramagnetic resonance (EPR), which is much less demanding for the homogeneity of magnetic field. On the other hand, it requires much more sensitive detection electronics, but Zavoisky was well prepared in this area. In particular he had replaced the calorimetric (thermal) detection of C. J. Gorter by a much more sensitive electronic technique of grid current. A further improvement was addition of a small AC magnetic field to the main static magnetic field. This dramatically increased the detection sensitivity and allowed easy amplification of the resonance signal and outputting it directly to an oscilloscope. In 1944, EPR signals were detected in several salts, including hydrous copper chloride (CuCl2·2H2O), copper sulfate and manganese sulfate.[6][12] The results were revolutionary and were first not accepted even by the Soviet scientists (including Pyotr Kapitsa). The doubts were dispersed when Zavoisky visited Moscow, assembled an EPR spectrometer from scratch and reproduced his results there.[3] In 1945, Zavoisky defended his habilitation on the phenomenon of electron paramagnetic resonance.[4][13][14]

Teaching

Zavoisky was a popular teacher who focused on demonstrations rather than theories. He himself showed various cryogenic phenomena, such as hardening and shattering of matter upon freezing. One experiment nearly resulted in his arrest by the internal police. Zavoisky demonstrated interference of polarized light in a biaxial crystal that resulted in an encircled swastika-like image projected onto the screen in front of a large audience. The demonstration crystals were soon confiscated and analyzed by a special commission, seeking relation between the experiment and Nazi Germany, and only a series of letters from scientists settled the matter.[15]

Late years

In 1947, upon invitation from Igor Kurchatov, Zavoisky moved from Kazan to Moscow, to work in the institute of the Russian Academy of Sciences which later became the Institute of Atomic Energy (IAE). He was then moved to the classified location Arzamas-16 and participated in the Soviet atomic bomb project. Upon return to IAE, he worked on detectors of ultrafast processes and in 1952 developed a novel luminescence camera for detection of nuclear processes.[13] Starting from 1958, he studied plasma and nuclear fusion related phenomena and discovered magneto-acoustic resonance in plasma in the same year.[6][14]

A serious illness took him away from science in 1972.[13] Zavoisky died in 1976 in Moscow.[6]

Awards and honors

Zavoisky was awarded the Stalin Prize (1949), the Lenin Prize (1957) and Hero of Socialist Labour (1969), as well as two Orders of Lenin. On 23 October 1953, he became an Associated Member of the Russian Academy of Sciences and on 26 June 1964 was elected as Academician.[3][16][17]

In 1977, a year after his death, his discovery of EPR was acknowledged by the international EPR society, which also established the "Zavoisky Award".[11] In 1984, Kazan Physics Institute was named after Zavoisky.[6][18]

Zavoisky received 17 nominations for the Nobel Prize between 1958 and 1966, of which 15 were in Physics and 2 in Chemistry.[19]

References

  1. Zavoisky, E. (1945). "Spin-magnetic resonance in paramagnetics". Fizicheskiĭ Zhurnal. 9: 211–245.
  2. Zavoisky, E. (1944). "Paramagnetic Absorption in Perpendicular and Parallel Fields for Salts, Solutions and Metals". PHD Thesis. Kazan State University.
  3. Gareth R. Eaton; et al. (1998). Foundations of modern EPR. World Scientific. pp. 45–46. ISBN 981-02-3295-0.
  4. Siegmund Brandt (2008). The harvest of a century: discoveries of modern physics in 100 episodes. Oxford University Press. p. 298. ISBN 978-0-19-954469-1.
  5. Kochelaev p. 44
  6. Завойский, Евгений Константинович. Krugosvet.ru (in Russian). Retrieved 2008-01-16.
  7. Kochelaev p. 50
  8. Kochelaev pp. 52–53
  9. I.I. Rabi; J.R. Zacharias; S. Millman; P. Kusch (1938). "A New Method of Measuring Nuclear Magnetic Moment". Physical Review. 53 (4): 318–327. Bibcode:1938PhRv...53..318R. doi:10.1103/PhysRev.53.318.
  10. Filler, Aaron (2009). "The History, Development and Impact of Computed Imaging in Neurological Diagnosis and Neurosurgery: CT, MRI, and DTI". Nature Precedings. doi:10.1038/npre.2009.3267.5.
  11. A.V. Kessenikh (September 2007). "On Academician E K Zavoisky's centenary". Soviet Physics Uspekhi. 50 (9): 977. Bibcode:2007PhyU...50..977K. doi:10.1070/PU2007v050n09ABEH006039. Russian pdf version
  12. Kochelaev p. 76
  13. А.П. Александров; et al. (April 1977). Памяти Евгения Константиновича Завойского. Soviet Physics Uspekhi (in Russian).
  14. Mario Bertolotti (2005). The history of the laser. CRC Press. p. 162. ISBN 0-7503-0911-3.
  15. Kochelaev pp. 54–57
  16. Завойский Евгений Константинович, at the official site of the Russian Academy of Sciences
  17. Завойский Евгений Константинович, entry in the Great Soviet Encyclopedia
  18. The International Zavoisky Award
  19. Yevgeny Konstantinovich Zavoisky, Nobel Prize Nomination Database

Bibliography

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