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Aleksandr Georgievich Tyurin (1953–2015) and his research in corrosion science

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Abstract

This paper is a tribute to one of the leading Russian scientists in the field of corrosion science and my supervisor, Aleksandr Georgievich Tyurin, who suddenly and unexpectedly passed away in 2015. A short biographical note is given together with an outline of his contributions to corrosion and electrochemical science.

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Notes

  1. In most cases, the scientific transliteration of Cyrillic alphabet according to the International Standard ISO 9:1995 “Information and documentation—Transliteration of Cyrillic characters into Latin characters—Slavic and non-Slavic languages” was applied. This includes the terms related to the Russian and Soviet academic system and the titles of articles, books and conferences in the References section. The first exception is Russian names and surnames. If applicable, they were written as in publications in English authored by these persons; otherwise, they were transliterated according to the rules of Federal Migration Service of Russian Federation for transliterating the names in visas and international passports. The second exception is Russian geographic names that were transliterated according to the rules issued by the US Board of Geographical Names.

  2. The English translations of the names of universities and institutes are given in the text. The original names are supplied in the subsequent notes.

  3. The official Russian name of Chelyabinsk Polytechnical Institute was Челябинский политехнический институт.

  4. The official Russian name of South Ural State National Research University is Южно-Уральский государственный университет (национальный исследовательский университет).

  5. In Russia and the former Soviet Union, the university diplomas of the students with outstanding examination results have a red cover sheet and red page background contrary to blue ones for the regular diplomas. This is why the diplomas with honours are called “the red diplomas”.

  6. The academic system of Russia and the former Soviet Union is two-stage. See the detailed description at https://en.wikipedia.org/w/index.php?title=Academic_ranks_in_Russia&oldid=726904556. Particularly, kandidat nauk and doktor nauk are, respectively, the first and the second academic degrees; assistent, mladšij naučnyj sotrudnik, docent and staršij naučnyj sotrudnik are the academic ranks available for the holders of the degree kandidat nauk; professor is the academic rank available for the holders of the degree doktor nauk. The form of post-graduate education, in which the applicant pursues the degree of kandidat nauk is called aspirantura and the applicant himself is called aspirant; the form of post-graduate education, in which the applicant pursues the degree of doktor nauk is called doktorantura and the applicant himself is called doktorant

  7. The translations are given in square brackets.

  8. The official Russian name of Ural Scientific-Research Institute of Pipe Industry was Уральский научно-технический институт трубной промышленности. The official Russian name of its successor, Russian Scientific-Research Institute of Pipe Industry, is Российский научно-технический институт трубной промышленности.

  9. The official Russian name of the Central Scientific-Research Institure of the Ferrous Metallurgy named after Ivan Pavlovich Bardin is Центральный научно-исследовательский институт чёрной металлургии имени Ивана Павловича Бардина.

  10. The official Russian name of Chelyabinsk State University is Челябинский государственный университет.

  11. Aleksandr Georgievich intentionally used the word “regular” in this term. In his opinion, it meant that whereas all the equations, proposed by Hildebrand for regular solutions, are still applicable together with his theory, the implementation of his model could help to bypass the limitations of Hildebrand’s theory.

  12. According to the Russian state standard “GOST 5632-2014 Legirovannye neržaveûŝie stali i splavy korrozionno-stojkie, žarostojkie i žaropročnye. Marki” [“Corrosion-resistant and heat-resistant alloyed stainless steels and alloys. Specifications”], the steel 08Х15Н5Д2Т contains the following (by weight %): C—0.08, Cr—14–16, Ni—4–6, Cu—2, Ti—1, Fe—the rest. According to the same state standard, the steel 12Х18Н10Т contains the following (by weight %): C—0.12, Cr—17–19, Ni—9–11, Ti—1, Fe—the rest. The steel Х13 contains the following (by weight %): C—0.5–0.7, Cr—12–14, Mn—0.25–0.80, Si—0.2–0.5, Fe—the rest.

  13. According to the Russian state standard “GOST 380-2005 Stal' uglerodistaâ obyknovennogo kačestva. Marki” [“Common quality carbon steel. Specifications”], the steel Ст.3 contains the following (by weight %): C—0.14–0.22, Si—0.15–0.3, Mn—0.4–0.65, Fe—the rest.

  14. According to the Russian state standard “GOST 15527-2004 Splavy medno-cinkovye (latuni), obrabatyvaemye davleniem. Marki” [“Copper-zinc alloys (brasses) treated by pressure. Specifications”], the siliceous brass ЛК80-3 contains the following (by weight %): Cu—79–81, Zn—13.5–18.5, Si—2.5–4. According to the same state standard, the leaded brass ЛС74-3 contains the following (by weight %): Cu—72–75, Zn—21.75–25.6, Pb—2.4–3.

  15. According to the Russian state standard “GOST 492-2006 Nikel', splavy nikelevye i medno-nikelevye, obrabatyvaemye davleniem. Marki” [“Nickel, nickel alloys and copper-nickel alloys treated by pressure. Specifications”], the melchior МН19 contains the following (by weight %): Ni + Co—18–20, Cu—the rest. According to the same state standard, the melchior МНЖМц30-1-1 contains (by weigth %): Ni + Co—29–33, Fe—0.5–1, Mn—0.5–1, Cu—the rest. Melchiors are sometimes called “a German silver”.

  16. The official Russian name of Samara State Technical University is Самарский государственный технический университет.

  17. The official Russian name of Murmansk State Technical University is Мурманский государственный технический университет.

  18. The official German name of University of Greifswald is Ernst-Moritz-Arndt-Universität Greifswald.

References

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  86. Nikolaychuk PA (2015). Das revidierte Pourbaix-Diagramm für Schwefel. In: Materialien zum wissenschaftlichen Seminar der Stipendiaten der Programme „Mikhail Lomonosov“ und „Immanuel Kant“. Moscow, Deutscher Akademischer Austausch Dienst und Ministerium für Bildung und Wissenschaft der RF 72–76.

  87. Nikolaychuk PA, Tyurin AG (2012) Termodinamika himičekoj i èlektrohimičeskoj ustojčivosti sistem Me – Si (Me = Ti, Mo, Mn, Fe, Co, Ni, Cu, Zn). In: Itogi dissertacionnyh issledovanij: Materialy IV Vserossijskogo konkursa molodyh učenyh. Moscow, RAN 1:54–68

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  94. Nikolaychuk PA, Tyurin AG (2013) Thermodynamic assessment of chemical and electrochemical stability of nickel–silicon system alloys. Corros Sci 73:237–244

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  95. Nikolaychuk PA, Tyurin AG (2013) Thermodynamic evaluation of corrosion-electrochemical behaviour of silicon brass CuZn17Si3. Inorg Mater 49(5):457–467

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  102. Tyurin AG, Vasekha MV, Biryukov AI (2016) Thermodynamic fundamentals of ferrous cake sulfitization. Russ Metall (Metally) 3:236–243

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  103. Chalaya EA, Tyurin AG, Vasekha MV, Biryukov AI (2016). Sintez i svojstva dvojnogo sul'fita medi (I) – nikelâ (II). Žurnal obŝej himii. Accepted.

  104. Tyurin AG, Kanatyeva II, Nikolaychuk PA (2013) Diagrammy himičeskoj i èlektrohimičeskoj ustojčivosti splavov sistemy Fe – Ge. In: Х Meždunarodnoe Kurnakovskoe soveŝanie po fiziko-himičeskomu analizu: sbornik trudov. Samara: Izdatel'stvo Samarskogo Gosudarstvennogo Tehničeskogo Universiteta 2:85–90

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  106. Tyurin AG, Nikolaychuk PA, Kabardin AM (2016) Thermodynamic evaluation of the corrosion-electrochemical behaviour of manganese–germanium system alloys. J Corros Sci Eng 19(20):1–38

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  107. Tyurin AG, Manannikov DA, Parshukov VP, Antonova AV, Nikolaychuk PA (2016). Method of estimation of corrosion stability of multicomponent alloys using equilibrium and polarization potential–pH diagrams. Anti-Corrosion Methods and Materials. Accepted.

  108. Tyurin AG, Manannikov DA, Parshukov VP, Nikolaychuk PA (2016) Korrozionno-èlektrohimičeskoe povedenie stali Х1312 v rastvore 5% NaCl + 0,5% CH3COOH + CH3COONa + CO2. J Corros Sci Eng 19(27):1–12

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  109. Tyurin, AG, Sharlay, EV (2016). Termodinamičeskij analiz korrozionno-èlektrohimičeskogo povedeniâ amorfnogo splava 2НСР. Vestnik Ûžno-Ural'skogo gosudarstvennogo universiteta. Seriâ “Himiâ”. Accepted. The soft magnetic amorphous alloy 2HCP is produced according to the Russian industry specifications “TU 14-123-149-2009 Lenta bystrozakalennaâ iz magnitomâgkih amorfnyh splavov i magnitomâgkogo kompozicionnogo (nanokristalličeskogo) materiala” [“A rapidly hardened tape from the soft magnetic amorphous alloys and the soft magnetic composite (nanocrystallic) materials”]. It contains (by weight %): Si – 5.3, B – 3.2, Ni – 1.8, Fe – the rest.

  110. Pratskova SE, Tyurin AG (2016) Modelirovanie kvazibinarov sistemy Na+, Ca2+ // O2–, F. Izvestiâ Vysših Učebnyh Zavedenij. Seriâ: Himiâ i Himičeskaâ Tehnologiâ 59(1):19–22

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  111. Nikolaychuk PA, Kolpakova AS, Tyurin AG (2016). Termodinamičeskaâ ocenka korrozionno-èlektrohimičeskogo povedeniâ svincovoj latuni ЛС74-314. Izvestiâ vysših učebnyh zavedenij. Cvetnaâ metallurgiâ. Accepted.

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Acknowledgments

I am very grateful to Prof. Fritz Scholz from University of GreifswaldFootnote 18, the Editor-in-Chief of Journal of Solid State Electrochemistry for his invitation to submit this article to this journal and for valuable discussion concerning the quality of this manuscript.

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  1. Čelâbinskij gosudarstvennyj universitet, Brat’ev Kaširinyh Street, 129, Chelyabinsk, Russian Federation, 454001

    Pavel Anatolyevich Nikolaychuk

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Nikolaychuk, P.A. Aleksandr Georgievich Tyurin (1953–2015) and his research in corrosion science. J Solid State Electrochem 21, 1–8 (2017). https://doi.org/10.1007/s10008-016-3327-z

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