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Issue 12, 2025
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1986

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June

  

New instruments and measurement methods


EXAFS spectroscopy: a new method for structural investigation

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EXAFS spectroscopy is a new method of investigating materials which allows one to determine structural parameters of the local environment of atoms with some specified $\mathbf{Z}$ by studying their x-ray spectra. Among these parameters are the interatomic spacings, coordination numbers and amplitudes of thermal oscillations. It is not necessary for long-range order to be present in the sample under investigation. Depending on the way this technique for obtaining the spectrum is applied, one can analyze the local environment of atoms located either within the sample volume or at its surface. We investigate the physical phenomena on which the method is based, the mathematical techniques used to process the experimental data, and various methods of recording the spectra. We present a series of examples in which EXAFS spectroscopy is used to study superionic conductors, compounds with intermediate valence, biological molecules, solid solutions, catalysts, surface layers and intercalated compounds.

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Fulltext is also available at DOI: 10.1070/PU1986v029n06ABEH003418
PACS: 78.70.Dm, 61.10.Ht (all)
DOI: 10.1070/PU1986v029n06ABEH003418
URL: https://ufn.ru/en/articles/1986/6/d/
Citation: Borovskii I B, Vedrinskii R V, Kraizman V L, Sachenko V P "EXAFS spectroscopy: a new method for structural investigation" Sov. Phys. Usp. 29 539–569 (1986)
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Оригинал: Боровский И Б, Ведринский Р В, Крайзман В Л, Саченко В П «EXAFS-спектроскопия — новый метод структурных исследований» УФН 149 275–324 (1986); DOI: 10.3367/UFNr.0149.198606d.0275

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  1. Ovchinnikova E N, Oreshko A P, Dmitrienko V E Uspekhi Fizicheskikh Nauk 195 (04) 416 (2025) [Ovchinnikova E N, Oreshko A P, Dmitrienko V E Phys. Usp. 68 (04) 393 (2025)]
  2. Korusenko P M, Petrova O V, Vinogradov A S Applied Sciences 14 (3) 1178 (2024)
  3. Choi H, Kim D H et al Electrochimica Acta 431 141138 (2022)
  4. Potudanskii G P, Peshkov Ya A, Kurganskii S I J. Phys.: Conf. Ser. 1902 (1) 012139 (2021)
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  6. Potudanskii G P, Kurganskii S I, Domashevskaya E P Mater. Res. Express 6 (11) 1150g9 (2019)
  7. Bakieva O R, Nemtsova O M Journal Of Electron Spectroscopy And Related Phenomena 222 15 (2018)
  8. (Proceedings of the International Conference "Mathematical Biology and Bioinformatics") Vol. Proceedings of the International Conference "Mathematical Biology and Bioinformatics"Reactive force-field molecular dynamic models of iron/oxide/carbon nanocomposites designed for magnetic hyperthermiaL.A.AvakyanA.S.ManukyanE.V.ParamonovaA.S.BogdanG.S.SukharinaE.G.SharoyanL.A.Bugaev7 (2018)
  9. Isomura N, Kosaka S et al Jpn. J. Appl. Phys. 57 (6) 060308 (2018)
  10. Avakyan L A, Bulat N V et al Bull. Russ. Acad. Sci. Phys. 80 (11) 1347 (2016)
  11. Avakyan L A, Srabionyan V V et al Opt. Spectrosc. 120 (6) 926 (2016)
  12. Fornasini P Synchrotron Radiation Chapter 6 (2015) p. 181
  13. Bakieva O R, Nemtsova O M, Surnin D V J. Synch. Investig. 9 (5) 1039 (2015)
  14. Menushenkov A P, Kuznetsov A V et al J Supercond Nov Magn 27 (4) 925 (2014)
  15. Dzyublik A Ya Phys. Rev. C 88 (5) (2013)
  16. Menushenkov A P, Kuznetsov A V et al J. Synch. Investig. 7 (3) 407 (2013)
  17. Kazak N V, Platunov M S et al J. Exp. Theor. Phys. 117 (1) 94 (2013)
  18. Moroz E M Theor Exp Chem 49 (2) 71 (2013)
  19. Srabionyan V V, Bugaev A L et al Journal Of Non-Crystalline Solids 382 24 (2013)
  20. Avakyan L A, Manukyan A S et al Opt. Spectrosc. 114 (3) 347 (2013)
  21. Belogorokhov A I, Orlov A F, Parkhomenko Yu N Inorg Mater 49 (15) 1331 (2013)
  22. Maevskiy A G, Rezvov V A et al Instrum Exp Tech 53 (1) 70 (2010)
  23. Trubina S, Erenburg S et al J. Phys.: Conf. Ser. 190 012128 (2009)
  24. Vedrinskiĭ R V, Kraĭzman V L et al Phys. Solid State 51 (7) 1394 (2009)
  25. Bugaev L A, Bokhoven Jeroen A van, Khrapko V V J. Phys. Chem. B 113 (14) 4614 (2009)
  26. Bugaev L A, Avakyan L A et al Opt. Spectrosc. 105 (6) 881 (2008)
  27. Bugaev L A, Latokha Ya V et al Opt. Spectrosc. 102 (6) 867 (2007)
  28. Kochur A G, Popov V A Opt. Spectrosc. 100 (5) 645 (2006)
  29. Bugaev L A, Latokha Ya V et al Opt. Spectrosc. 100 (4) 563 (2006)
  30. Bugaev L A, van Bokhoven Je A et al J. Phys. Chem. B 109 (21) 10771 (2005)
  31. Bugaev L A, Sokolenko A P et al Phys. Rev. B 65 (2) (2001)
  32. Bugaev L A, Shuvaeva V A et al Phys. Solid State 40 (6) 1001 (1998)
  33. Shevelko V P Atoms and Their Spectroscopic Properties Chapter 4 (1997) p. 90
  34. Bondarchuk A B, Goysa S N et al Surface Science 258 (1-3) 239 (1991)
  35. Gegsin I I, Datsyuk V N et al Physica Status Solidi (b) 151 (2) 581 (1989)
  36. Shuvayev A T, Helmer B Yu et al J. Phys. France 50 (10) 1145 (1989)
  37. Kondratenko A V, Fomin � S et al J Struct Chem 30 (2) 249 (1989)
  38. Vedrinskii R V, Bugaev L A, Levin I G Physica Status Solidi (b) 150 (1) 307 (1988)
  39. Bart Ja C J, Vlaic G Advances In Catalysis Vol. 35 (1987) p. 1
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