О возможности существования неорганических стекол, обладающих пластичностью при температурах ниже температуры размягчения

Cover Page

Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription Access

Full Text

Restricted Access

About the authors

Ю. С. Тверьянович

Санкт-Петербургский государственный университет

Author for correspondence.
Email: tys@bk.ru
Russian Federation, Санкт-Петербург

References

  1. Januchta K., Stepniewska M., Jensen L. R., Zhang Y., Somers M. A. J., Bauchy M., Smedskjaer M. M. Breaking the Limit of Micro‐Ductility in Oxide Glasses. // Advanced Science, 2019. № 1901281.
  2. Redmond K. Oxide glass exhibits plasticity without fracture at room temperature. //MRS Bulletin. 2020. V.45, P. 78–79
  3. Frankberg E. J., Kalikka J., García Ferré F., Joly-Pottuz L., Salminen T., Hintikka J., Masenelli-Varlot K. Highly ductile amorphous oxide at room temperature and high strain rate. Science, 2019. 366(6467), P. 864–869.
  4. Vandembroucq D.; Deschamps T.; Coussa C.; Perriot A.; Barthel E.; Champagnon B.; Martinet C. Density Hardening Plasticity and Mechanical Ageing of Silica Glass under Pressure: A Raman Spectroscopic Study. // J. Phys.: Condens. Matter 2008, V.20, No. 485221.
  5. Lee K. H.; Yang Y.; Ding L.; Ziebarth B.; Davis M. J.; Mauro J. C. Plasticity of Borosilicate Glasses under Uniaxial Tension. // J. Am. Ceram. Soc. 2020, V.103, P. 4295–4303.
  6. Varshneya A. K.; Mauro D. J. Microhardness, Indentation Toughness, Elasticity, Plasticity, and Brittleness of Ge-Sb-Se Chalcogenide Glasses. // J. Non-Cryst. Solids 2007, V.353, P. 1291–1297.
  7. Yannopoulos N. Intramolecular Structural Model for Photoinduced Plasticity in Chalcogenide Glasses. // Phys. Rev. B: Condens. Matter Mater. Phys. 2003, V.68, P. 1–7.
  8. Milman Y. V.; Chugunova S. I.; Goncharova I. V.; Golubenko A. A. Plasticity of Materials Determined by the Indentation Method. // Prog. Phys. Met. 2018. V.19. P. 271–308.
  9. Tveryanovich Y. S., Fazletdinov T. R., Tverjanovich A. S., Pankin D. V., Smirnov E. V., Tolochko O. V., Panov M. S., Churbanov M. F., Skripachev I. V., Shevelko M. M. Increasing the Plasticity of Chalcogenide Glasses in the System Ag2Se–Sb2Se3–GeSe2 //Chem. Mater. 2022. V. 34. N6. 2743–2751.
  10. Tver’yanovich Y.S., Fazletdinov T. R., Tomaev V. V. Peculiarities of the Effect of Silver Chalcogenides on the Glass-Formation Temperature of Chalcogenide Glasses with Ionic Conduction. // Russ J Electrochem. 2023. V.59. 567–572.
  11. Evarestov R.A, Panin A.I, Tverjanovich Y. S. Argentophillic interactions in argentum chalcogenides: First principles calculations and topological analysis of electron density. // Journal of Computational Chemistry. 2021. V. 42, № 4. P. 242–247.
  12. Bychkov, E.; Price, D. L.; Benmore, C. J.; Hannon, A. C. Ion Transport Regimes in Chalcogenide and Chalcohalide Glasses: From the Host to the Cation-Related Network Connectivity. // Solid State Ionics 2002. N154–155. P. 349–359.
  13. Salmon, P. S.; Xin, S.; Fischer, H. E. Structure of the glassy fashion conductor AgPS3 by neutron diffraction. // Phys. Rev. B1998. V.58. P. 6115–6123.
  14. Akola, J.; Jovari, P.; Kaban, I.; Voleska, I.; Kolar, J.; Wagner, T.; Jones, R. O. Structure, electronic, and vibrational properties of amorphous AsS2 and AgAsS2: Experimentally constrained density functional study. // Phys. Rev. B2014. 89. № 064202.
  15. Borisova, Z. Glassy Semiconductors // Springer US, 1981.
  16. Tveryanovich Yu. S., Fazletdinov T. R., Tverjanovich A. S., Fadin Yu. A., Nikolskii A. B. Features of Chemical Interactions in Silver Chalcogenides Causing Their High Plasticity. // Russian Journal of General Chemistry. 2020. V.90. N11. P. 2203–2204.
  17. Tveryanovich Y. S., Razumtcev A. A., Fazletdinov T. R., Krzhizhanovskaya M. G., Borisov E. N. Stabilization of high-temperature Ag2Se phase at room temperature during the crystallization of an amorphous film. // Thin Solid Films. 2020.V. 709. № 1. N138187.
  18. Wang Y., Mitkova M., Georgiev D. G., Mamedov S., Boolchand P. Macroscopic phase separation of Se-rich (x < 1/3) ternary Agy(GexSe1–x)1–y glasses.// J. Phys.: Condens. Matter. 2003. 15. S1573–S1584.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download
2. Fig. 1. Dependences of glass plasticity according to Milman on the temperature of measurements, expressed in fractions of Tg of the corresponding glass. circles - glasses of the As2S3 - Tl2S system (calculation using experimental data [15]); squares - glasses of the Sb-Ge-Se system (calculation using experimental data [15]); asterisks - experimental data for glasses of the (0.73GeSe2*0.27Sb2Se3)-Ag2Se system [9]

Download (58KB)
Indexing metadata

Copyright (c) 2024 Russian Academy of Sciences