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Modern aspects of the kinetic theory of glass transition

 a,  b, c,  a, d
a Frank Neutron Physics Laboratory, Joint Institute of Nuclear Research, Dubna, Moscow Region, Russian Federation
b Joint Institute for Nuclear Research, Bogoliubov Laboratory of Theoretical Physics, Dubna, Moscow Region, Russian Federation
c Universität Rostock, Universitatsplatz 1, Rostock, 18051, Germany
d The National Research Center "Kurchatov Institute", Konstantinov Petersburg Nuclear Physics Institute, Orlova Roshcha, Gatchina, Leningradskaya Region, 188300, Russian Federation

This paper reviews glass transition kinetics models that are used to describe the formation of structural (for example, covalent and metallic) glasses as well as to account for the transition of a polymer to a solid glassy state. As the two approaches most used to model the glass transition over the last decade, the Tool—Narayanaswamy—Moynihan model and the Adam—Gibbs theory of the glass transition are described together with examples of their applications. Also discussed are entropy-based approaches that rely on irreversible thermodynamics methods originated in the work of De Donder, Mandelstam, and Leontovich. The actual problems that arise in application of these methods and the perspectives of their development are discussed. A brief overview on statistical glass transition models is given, including the mode-coupling and energy-landscape theories.

Fulltext pdf (898 KB)
Fulltext is also available at DOI: 10.3367/UFNe.0186.201601c.0047
Keywords: glass transition, kinetics of glass transition, polymer glass transition, theory and modeling of glass transition, thermal properties of amorphous solids and glasses
PACS: 61.43.Fs, 64.70.kj, 64.70.Q− (all)
DOI: 10.3367/UFNe.0186.201601c.0047
URL: https://ufn.ru/en/articles/2016/1/c/
000374119000002
2-s2.0-84962910922
2016PhyU...59...42T
Citation: Tropin T V, Schmelzer Ju W P, Aksenov V L "Modern aspects of the kinetic theory of glass transition" Phys. Usp. 59 42–66 (2016)
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Received: 17th, July 2015, revised: 8th, October 2015, 10th, October 2015

Оригинал: Тропин Т В, Шмельцер Ю В П, Аксенов В Л «Современные аспекты кинетической теории стеклования» УФН 186 47–73 (2016); DOI: 10.3367/UFNr.0186.201601c.0047

References (261) Cited by (71) ↓ Similar articles (20)

  1. Burkinshaw S M Coloration Technology 140 149 (2024)
  2. Kondratyuk N D, Pisarev V V Uspekhi Fizicheskikh Nauk 193 437 (2023)
  3. [Kondratyuk N D, Pisarev V V Phys. Usp. 66 410 (2023)]
  4. Negahban M, Li W et al 67 749 (2023)
  5. Gridnev S A, Kalinin Y E Tech. Phys. 68 S532 (2023)
  6. Kelton K F 134 (1) (2023)
  7. Kaur R, Bhattacharya D et al 158 (16) (2023)
  8. Lebedev M P, Startsev O V Russ Chem Bull 72 553 (2023)
  9. Lapuk S E, Mukhametzyanov T A et al Mol. Pharmaceutics 20 3202 (2023)
  10. Vasin M, Ankudinov V Math Methods In App Sciences (2023)
  11. Lapuk S E, Ponomareva M A et al Macromolecules 55 4516 (2022)
  12. Sanditov D S, Mashanov A A Inorg Mater 58 630 (2022)
  13. Yuritsyn N S, Fokin V M et al Journal Of Non-Crystalline Solids 590 121669 (2022)
  14. Kausar A Materials Research Innovations 26 52 (2022)
  15. Zhang R, Madhavi V et al Macro Chemistry & Physics 223 (15) (2022)
  16. Schmelzer J W P, Tropin T V Int J Of Appl Glass Sci 13 171 (2022)
  17. Kalinin Yu E, Kudrin A M et al Polym. Sci. Ser. A 64 1 (2022)
  18. Gridnev S A, Kalinin Yu E et al Journal Of Alloys And Compounds 918 165610 (2022)
  19. Lu A K A, Louzguine-Luzgin D V 157 (1) (2022)
  20. Sanditov D S, Sangadiev S Sh Dokl. Phys. 66 97 (2021)
  21. Argatov I, Kocherbitov V Continuum Mech. Thermodyn. 33 107 (2021)
  22. Cheng S, Wojnarowska Z et al 154 (4) (2021)
  23. Khodko O Probl Cryobiol Cryomed 31 236 (2021)
  24. Pu Z, Huang J et al Journal Of Non-Crystalline Solids 563 120817 (2021)
  25. Yuritsyn N S, Fokin V M et al SSRN Journal (2021)
  26. Lukichev A A Journal Of Non-Crystalline Solids 555 120618 (2021)
  27. Alonso Ju M, Sanchez-Varretti F O, Frechero M A Eur. Phys. J. E 44 (7) (2021)
  28. Lyubimova O N, Barbotko M A Thermophys. Aeromech. 28 87 (2021)
  29. Startsev O V, Vapirov Yu M et al Mech Compos Mater 56 227 (2020)
  30. Sanditov D S, Ojovan M I, Darmaev M V Physica B: Condensed Matter 582 411914 (2020)
  31. Schmelzer J W P, Tropin T V et al Entropy 22 1098 (2020)
  32. Sanditov D S, Badmaev S S Inorg Mater 56 518 (2020)
  33. Sanditov D S, Mashanov A A, Darmaev M V Polym. Sci. Ser. A 62 79 (2020)
  34. Li J, Jangid R et al Sci Rep 10 (1) (2020)
  35. Sanditov D S, Sangadiev S Sh, Darmaev M V IOP Conf. Ser.: Mater. Sci. Eng. 1000 012003 (2020)
  36. Sanditov D S, Razumovskaya I V, Mashanov A A Polym. Sci. Ser. A 62 588 (2020)
  37. Sanditov D S, Mantatov V V, Sangadiev S Sh Phys. Solid State 62 1924 (2020)
  38. Brazhkin V V Jetp Lett. 112 745 (2020)
  39. Terekhov S V Phys. Metals Metallogr. 121 664 (2020)
  40. Mokshin A V, Galimzyanov B N, Yarullin D T Jetp Lett. 110 511 (2019)
  41. Lyubimova O N, Barbotko M A Comp. Contin. Mech. 12 215 (2019)
  42. Schmelzer J W P, Tropin T V Thermochimica Acta 677 42 (2019)
  43. Sanditov D S, Badmaev S S Inorg Mater 55 1046 (2019)
  44. Wang M, Fang L et al Ceramics International 45 4351 (2019)
  45. Brazhkin V V Phys.-Usp. 62 623 (2019)
  46. Sanditov D S, Ojovan M I Uspekhi Fizicheskikh Nauk 189 113 (2019) [Sanditov D S, Ojovan M I Phys.-Usp. 62 111 (2019)]
  47. Cubeta U S, Sadtchenko V 150 (9) (2019)
  48. Sanditov D S, Mashanov A A Polym. Sci. Ser. A 61 119 (2019)
  49. Schmelzer J W P, Tropin T V et al Int J Of Appl Glass Sci 10 502 (2019)
  50. Schmelzer J W P, Abyzov A S et al Journal Of Non-Crystalline Solids 501 21 (2018)
  51. Aksenov V L, Tropin T V, Schmelzer J V P Theor Math Phys 194 142 (2018)
  52. Schmelzer J, Tropin T Entropy 20 103 (2018)
  53. Burenin A A, Lyubimova O N, Solonenko E P J Appl Mech Tech Phy 59 1095 (2018)
  54. Perez-De E N G, Cangialosi D Phys. Chem. Chem. Phys. 20 12356 (2018)
  55. Pan Zh, Zhou Yu et al Polymer International 67 1677 (2018)
  56. Cangialosi D Handbook Of Thermal Analysis And Calorimetry Vol. Recent Advances, Techniques and ApplicationsGlass Transition and Physical Aging of Confined Polymers Investigated by Calorimetric Techniques6 (2018) p. 301
  57. Nucleation and Crystal Growth 1 (2018) p. 423
  58. Mohammadi M, fazli Hossein et al European Polymer Journal 91 121 (2017)
  59. Sanditov D S, Mashanov A A, Darmaev M V Phys. Solid State 59 348 (2017)
  60. Cubeta U, Bhattacharya D, Sadtchenko V 147 (7) (2017)
  61. Sanditov D S, Mashanov A A Doklady Akademii Nauk (6) 681 (2017)
  62. Sanditov D S, Darmaev M V, Sanditov B D Tech. Phys. 62 53 (2017)
  63. Boucher V M, Cangialosi D et al 146 (20) (2017)
  64. Boucher V M, Cangialosi D et al Phys. Chem. Chem. Phys. 19 961 (2017)
  65. Sanditov D S, Ojovan M I Physica B: Condensed Matter 523 96 (2017)
  66. Ilyushin M A, Kozlov A S et al Glass Phys Chem 43 111 (2017)
  67. Sanditov D S, Mashanov A A Dokl Phys Chem 477 231 (2017)
  68. Sanditov D S, Sangadiev S Sh, Darmaev M V Phys. Solid State 58 2078 (2016)
  69. Sanditov D S, Mashanov A A Russ. J. Phys. Chem. 90 2492 (2016)
  70. Lyubimova O N, Solonenko E P J. Phys.: Conf. Ser. 754 082002 (2016)
  71. Sanditov D S J. Exp. Theor. Phys. 123 429 (2016)

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