Jump to content

Ivan Alimarin

From Wikipedia, the free encyclopedia
(Redirected from Draft:Ivan Alimarin)
Ivan Alimarin
Born11 September [O.S. 29 August] 1903
Died17 December 1989(1989-12-17) (aged 86)
Moscow, Soviet Union
Resting placeMoscow, Rogozhsky cemetery
CitizenshipRussian Empire, Soviet Union
Alma materMoscow State University
AwardsHero of Socialist Labour, Order of Lenin, USSR State Prize
Scientific career
FieldsAnalytical chemistry
InstitutionsMoscow State University, Moscow State University of Fine Chemical Technologies

Ivan Pavlovich Alimarin (Russian: Иван Павлович Алимарин, September 11, 1903 - December 17, 1989) was a Soviet analytical chemist, academician of the Academy of Sciences of the Soviet Union (1966), Laureate of the State Prize of the USSR (1972), and Hero of Socialist Labor (1980). Alimarin's scientific activity covered several problems in analytical chemistry, including mineral analysis, and impurity detection in semiconductors.

Biography

[edit]

Chronology

[edit]

Early years

[edit]

Alimarin was born into a family of civil servants. His father was an accountant.[4] Alimarin graduated from the Moscow City Elementary School in 1915 and entered the Moscow Commercial School,[1] where he first displayed interest in the natural sciences. During his time at the Moscow Commercial School, Alimarin studied analytical chemistry from a book by Nikolai Menshutkin. Alimarin's interest in chemistry was noticed by his petrography professor, whom he cites as an influence.[1]

Further life

[edit]

In the 1920s, Alimarin worked as a laboratory assistant and chemistry teacher at the Plekhanov Institute of National Economy. Alimarin supervised inorganic and analytical chemistry courses under the guidance of his professors. In 1923, after graduating from college, Alimarin was invited to the Institute of Applied Mineralogy (known today as the All-Union Institute of Mineral Raw Materials), where he would conduct most of his petrochemical research.[2]

In 1935, without defending his thesis, Alimarin received the degree of Candidate of Chemical Sciences and the title of Senior Researcher.[2] At the same time, he took up employment at the Moscow Institute of Fine Chemical Technology (MITHT), where he worked as an assistant (1929-1935) and later as a laboratory head and associate professor (1935-1941).[1]

When World War II began, Alimarin was evacuated along with the entire Institute of Applied Mineralogy to the Chelyabinsk region. He continued his research[1] until his return in 1943, upon which he was appointed head of the analytical chemistry department of the MITHT.[11] At the same time, he continued to work at the Institute of Applied Mineralogy, where he created the first inorganic microanalysis laboratory in the USSR. Alimarin also founded a school for analytical chemistry during this time.[1]

In 1953, Alimarin was elected a corresponding member of the USSR Academy of Sciences. He acquired full membership in 1966.[7]

From 1953 onward, Alimarin worked as the head of the analytical chemistry department at MSU's faculty of chemistry, succeeding Professor Evgenii Przhevalsky.[5] Alimarin and his students continued to develop the field of analytical chemistry.[12]

Scientific activity

[edit]

Developments in theoretical analytical chemistry

[edit]

Alimarin was interested in the theoretical problems of analytical chemistry, including the composition and structure of organometallic compounds and the theoretical bases of chelate extraction and distribution chromatography. Many of the methods Alimarin developed are still employed today, both in laboratory and industrial settings.[12]

Methods for determining trace elements in raw minerals

[edit]

At the beginning of his scientific career, Alimarin carried out a series of studies on methods for determining the presence of trace boron and fluorine in minerals, since at the time there existed no efficient methods that accomplished this. In 1929, Alimarin proposed a colorimetric method for determining the presence of trace fluorine in minerals based on its capacity to form a stable zirconium-fluorine complex from zirconium-oxy-anthraquinone.[2] He also developed efficient methods for the titrimetric determination of boron in various minerals.[4] Alimarin also developed similar methods for niobium, tantalum, titanium,[13] zirconium, scandium,[14] gallium, and indium.[15]

Developments in microanalysis

[edit]

Alimarin developed microanalytic methods for determining the presence of nitrous oxide and iron oxide in minerals and water, and of silicic acid in silicates before the war. During his time in Chelyabinsk, Alimarin developed similar methods for tin, tungsten, molybdenum, cobalt, vanadium and mercury. He also made contributions to metallurgy and created a microanalysis laboratory.[5]

After his return from Chelyabinsk, Alimarin continued his work in microanalysis, using various methods borrowed from physical chemistry.[16] More microanalysis laboratories were created at GEOHI and the Department of Analytical Chemistry of MSU under his direction. He also proposed coulometric microtitrations[12] and introduced the study of ion-selective electrodes for determining the presence of trace elements in small-volume solutions. He also worked on the development of electron microscopy in cooperation with the Institute of Technical Physics of the Hungarian Academy of Sciences. Among the results of this collaboration was the development of a quantitative method for the X-ray spectral microanalysis of thin layers (of up to 100 nm) in a transmission electron microscope, which allowed for determining the chemical composition of microscopic objects without their destruction with an absolute detection limit of up to 10-18 g.[17][18]

Analysis of highly pure substances

[edit]

A significant part of Alimarin's scientific activity was focused on developing methods for separating and determining the concentration of small and ultra-small concentrations of elements, i.e. "trace" analytical chemistry. An important application of these studies is analyzing the purity of substances used in nuclear power plants, semiconductors, radio electronics and optical fibres. Alimarin's teams at GEOHI and MSU created methods for the analysis of high-purity substances, which allowed them to find a large number of impurities with detection limits of 10-5-10-9%.[5] These methods involved activation analysis,[19] inversion voltammetry,[20] luminescence,[21] laser spectroscopy,[22] catalytic reactions,[23] extraction chromatography,[24] co-deposition with atomic emission,[12] atomic absorption, spectrophotometric determination, as well as certain combined methods.[25]

These methods represented an important advance in quality control and remain relevant in the science of obtaining the pure substances themselves. In 1972, Alimarin was awarded the USSR State Prize for his work in this field.[26]

Nuclear chemistry and radio analysis

[edit]

Alimarin began working on nuclear chemistry in 1950. His studies served as seminal papers on the development of radioanalytical methods for determining the presence of trace elements, such as activation analysis,[19] isotope dilution and radiometric titration.[27]

Chromatography and electrochemistry

[edit]

Alimarin carried out numerous ionic, gas-liquid and liquid-liquid chromatography studies at MSU to identify patterns of ion sorption on surface-modifiedsorbents.[7] Based on these studies, new chromatographic methods were developed for separating several elements and many accompanying ion exchangers modified with organic reagents (heterocyclic azo compounds).[28] Effective sorption-photometric methods were developed for the concentration and determination of palladium, copper and some other elements.[29] Under the leadership of Alimarin, MSU and GEOHI developed a method for the determination of ultra-low concentrations of substances in 1960. This method is known today as inversion voltammetry.[12] Alimarin also developed an oscillographic version of inversion polarography, which was 2-3 times more effective than the standard method of his time.[30] Alimarin was also involved in the development of potentiometry and coulometry methods at MSU.[31] At GEOHI, Alimarin developed controlled potential coulometry for determining the presence of trace platinum.[32]

Luminescence analysis

[edit]

Alimarin began research on photoluminescence in 1963 at MSU. He developed highly sensitive (detection limit 10-4-10-7%) methods for determining the presence of gallium, indium, tantalum, tellurium, uranium, thorium and other elements in semiconductor materials, ores, waters, and chemical reagents.[33][34][35] In the following years, Alimarin studied low-temperature luminescence (cryo-luminescence) in aqueous solutions and extracts of halide complexes of transition metals.[7] His methods are sometimes used to analyze the composition of semiconductor materials in electronics.[36]

Contributions to the history of science

[edit]

Alimarin's works on the history of Russian science emphasized the importance of Mikhail Lomonosov and Dmitri Mendeleev's studies. Alimarin also considered the study of platinum and the platinum group to be important in analytical chemistry.[12] Alimarin co-authored a 1967 paper covering the developments of Russian analytical chemistry in the first half of the 19th century. Alimarin also advocated for the development of analytical chemistry and believed it to be a promising field of study.[37]

Alimarin presented his views on the general issues of analytical chemistry, such as its name and its importance, in a 1983 article titled "Modern Understanding of the Science of analytical chemistry".[38][39]

Pedagogy

[edit]

Alimarin held various teaching positions throughout his career. His lectures at the MITHT and later at the MSU focused on the practical aspects of analytical chemistry.[40] Alimarin taught a general analytical chemistry course for second-year students at the Faculty of Chemistry at MSU and a special course on modern methods for students specializing in analytical chemistry. Over 80 doctorate theses were completed with Alimarin's guidance. Another 18 doctoral theses were defended with his advisory participation.[2]

Aliman also co-authored a textbook on analytical chemistry.[41]

Legacy

[edit]

The Department of Analytical Chemistry at MITHT is named after him.[11]

References

[edit]
  1. ^ a b c d e f g "Ivan Pavlovich Alimarin" (PDF). rea.ru.
  2. ^ a b c d e f "Academician Alimarin Ivan Pavlovich". Archived from the original on 2022-02-25.
  3. ^ a b "Alimarin Ivan Pavlovich". Archived from the original on 2023-03-25.
  4. ^ a b c "100 years since the birth of Academician Ivan Pavlovich Alimarin". ANCHEM.RU. Archived from the original on 2023-11-20.
  5. ^ a b c d "I.P. Alimarin". Archived from the original on 2021-10-17.
  6. ^ "Thesis catalog". Archived from the original on 2013-03-19. Retrieved 2010-11-11.
  7. ^ a b c d Zolotov, Y.A.; Oskolok, K.V., eds. (2017). Department of Analytical Chemistry, Lomonosov Moscow University. Moscow: PRESS-BOOK.RU. p. 278. ISBN 978-5-9909574-6-6.
  8. ^ Laboratory of Radioanalytical and Electrochemical Methods Archived 2009-04-13 at the Wayback Machine
  9. ^ "Alimarin Ivan Pavlovich". National Heroes. Archived from the original on 2022-02-21.
  10. ^ "Moscow tombs. Alimarin I.P." Archived from the original on 2014-08-10. Retrieved 2014-08-03.
  11. ^ a b "Official website of the Department of Analytical Chemistry, M.V. Lomonosov MITHT". Archived from the original on 2014-10-29. Retrieved 2014-08-07.
  12. ^ a b c d e f Ivan Pavlovich Alimarin. Essays. Memories. Materials. M.: Nauka, 1993. 158 с. ISBN 5-02-001636-5
  13. ^ Alimarin, I.P.; Gibalo, I.M. (1956). "Extraction of niobium, tantalum and titanium kupferonates". Papers of the USSR Academy of Sciences. 109: 1137–1139.
  14. ^ Putilina, V.S.; Fadeeva, V.I.; Alimarin, I.P. (1973). "Extraction of tenoyltrifluoroacetonates of zirconium and scandium in the presence of diamidheptyl phosphate from mineral acid solutions". Bulletin of Moscow University. 14 (2): 120–122.
  15. ^ Golovina, A.P.; Hvatkova, Z.M.; Zorov, N.B.; Alimarin, I.P. (1972). "Asymmetric Rhodamine Dyes as Extraction and Fluorimetric Reagents for Gallium and Indium". Bulletin of Moscow University. 13 (5): 551–555.
  16. ^ Alimarin, I.P.; Frid, B.I. (1961). Quantitative microchemical analysis of minerals, ores and rocks. Moscow: Goshimizdat. p. 399.
  17. ^ Alimarin, I.P.; Petrikova, M.N. (1960). Inorganic ultromicroanalysis. Moscow: AS USSR. p. 152.
  18. ^ Alimarin, I.P.; Petrikova, M.N. (1974). Qualitative and quantitative ultromicrochemical analysis. Moscow: Himiya. p. 286.
  19. ^ a b Alimarin, I.P.; Yakovlev, Y.V. (1969). "Nuclear-physical methods of analysis". Atomic Energy. 26 (2): 127–132.
  20. ^ Alimarin, I.P.; Vinogradova, E.N.; Kamenev, A.I. (1972). "Inversion-voltammetric determination of trace elements on a hanging mercury drop". Chem. Anal. 17: 459–467.
  21. ^ Golovina, A.P.; Levshin, L.V. (1978). Chemical luminescence analysis of inorganic substances. Moscow: Himiya.
  22. ^ Kuzyakov, Yu.Ya.; Zorov, N.B.; Chaplygin, V.I.; Novodvorsky, O.A. (1983). "Trace Analysis by Laser Optogalvanic Spectroscopy". Journal de Physique. 44 (7): 335–343.
  23. ^ Dolmanova, I.F.; Ershova, E.V.; Shekhovtsova, T.N.; Nad', V.Y. (1979). "Kinetic determination of microquantities of mercury using peroxidase enzyme". Journal of Analytical Chemistry. 34 (12): 1644–1647.
  24. ^ Alimarin, I.P.; Bolshova, T.A.; Bakhareva, G.A. (1973). "Separation of indium (III) and antimony (V) by extraction chromatography". Journal of Analytical Chemistry. 28 (8): 1300–1303.
  25. ^ Alimarin, I.P.; Zolotov, Y.A. (1962). "Extraction in chemical analysis". Industrial Laboratory. 28 (11): 1365–1366.
  26. ^ Ivanov, V.M.; Kolotov, V.P.; Ostroumov, G.V. (2003). "Academician Ivan Pavlovich Alimarin (1903-1989): On the 100th anniversary of his birth". Zavodskaya Laboratoriya. Diagnostika Materialov. 69 (8): 7–13. ISSN 1028-6861.
  27. ^ Alimarin, I.P. (1955). "Applications of radioactive isotopes in chemical analysis". Applications of isotopes in technology, biology and agriculture: reports of the Soviet delegation. Moscow: AS USSR. pp. 152–180.
  28. ^ Brykina, G.D.; Stepanova, N.L.; Belyavskaya, T.A. (1982). "Effect of adsorption of 1-(2-thiazolylazo)-2-naphthol and its derivatives during modification of sorbent AV-17 on the complexation ability of these reagents". Journal of Analytical Chemistry. 36 (2): 52–57.
  29. ^ Alimarin, I.P.; Nikitin, I.S.; Ivanov, V.M.; Bolshova, T.A.; Basova, E.M.; Morozova, N.B. (1986). "High-Performance Liquid-Chromatography of 1-(2-pyridylazo)-2-naphtholates of Palladium, Rhodium, and Platinum". Akademiia Nauk SSSR. 288 (5): 1112–1115.
  30. ^ Zolotov, Y.A., ed. (2015). Chemical analysis on the road to excellence. Department of Analytical Chemistry. Moscow: LENAND. pp. 223–234.
  31. ^ Agasjan, P.K.; Drapkin, M.Y.; Shestopalov, G.N.; Kamenev, A.I. (1979). "Heavy metals determination by chronopotentiometric control of natural and industrial sewage waters". VIII IMEKO Congress. Moscow: 1773–1778.
  32. ^ "Potentiostatic coulometry". GEOHI RAS. Archived from the original on 2021-01-24.
  33. ^ SU patent 947759, "Gold Luminescent Determination Method", issued 1982-04-14 
  34. ^ SU patent 1122613, "Method for Detecting Ruthenium", issued 1984-11-04 
  35. ^ SU patent 1083110, "Europium Determination Method", issued 1984-03-30 
  36. ^ Runov, V.K. (1994). Development of optical sorption-molecular spectroscopic methods of analysis (Doctor of Sciences in Chemical Sciences thesis). Moscow State University.
  37. ^ Alimarin, I.P.; Zolotov, Y.A. (1975). "Prospective Developments in Analytical-Chemistry". Journal of Analytical Chemistry of the USSR. 30 (7): 1059–1064.
  38. ^ Alimarin, I.P. (1983). "Current understanding of the science of "analytical chemistry"". Journal of Analytical Chemistry. 38 (3): 540–556.
  39. ^ "Ivan Pavlovich Alimarin (On the 100th anniversary of his birth)". Moscow University. No. 29. 2003.
  40. ^ Alimarin, I.P.; Fadeeva, V.I.; Dorohova, E.N. (1976). Lecture experiments in analytical chemistry. Moscow: Mir. p. 306.
  41. ^ Alimarin, I.P.; Ushakova, N.N. (1977). Analytical Chemistry Reference Manual. Moscow: MSU. p. 102.

Literature

[edit]
  • "Alimarin I. P., To the sixtieth anniversary of his birth". Zavodskaya Lavoratoriya. 29 (9). 1963.
  • Zolotov, Y.A.; Petrikova, M.N., eds. (1974). Advances in analytical chemistry. Moscow: Nauka. p. 358.
  • Sherbina, E. (1978). "For the glory of science. Jubilee of a scientist". Moscow University. No. 38.
  • Ivan Pavlovich Alimarin. Essays. Memories. Materials. Moscow: Nauka. 1993. p. 158. ISBN 5-02-001636-5.
  • Ivanov, V.M.; Kolotov, V.P.; Ostroumov, G.V. (2003). "Academician Ivan Pavlovich Alimarin (1903-1989): On the 100th anniversary of his birth". Zavodskaya Laboratoriya. Diagnostika Materialov. 69 (8): 7–13. ISSN 1028-6861.
  • "Ivan Pavlovich Alimarin (On the 100th anniversary of his birth)". Moscow University. No. 29. 2003.
  • Mavrina, T.V.; Popov, V.A. (2003). Plate, N.A. (ed.). Russian science in persons. Moscow: Academia. p. 3. ISBN 5-87444-208-1.
  • Bogunenko, N.N.; Pelipenko, A.D.; Sosnin, G.A.; Belov, A.S. (2005). Heroes of the atomic project. Sarov: Rosatom. p. 43. ISBN 5-9515-0005-2.
  • Prohorov, A.M., ed. (1969–1978). Alimarin Ivan Pavlovich // Great Soviet Encyclopedia. Moscow: Sovetskaya Enciclopediya.
[edit]