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Teplofizika vysokikh temperatur, 2014, Volume 52, Issue 4, Pages 563–567
DOI: https://doi.org/10.7868/S0040364414030168
(Mi tvt621)
 

This article is cited in 29 scientific papers (total in 29 papers)

Thermophysical Properties of Materials

Thermal Expansion of Beryllium Oxide in the Temperature Interval $20$$1550^{\circ}$C

Yu. M. Kozlovskiy, S. V. Stankus

S.S. Kutateladze Institute of Heat Physics, Siberian Division of the Russian Academy of Sciences
References:
Abstract: The results of studies of thermal expansion of the sintered beryllium oxide within the temperature interval $20$$1550^{\circ}$C are presented. Measurements were performed by a dilatometric method on a DIL–402C set-up manufactured by NETZSCH (Germany), with the accuracy of $(1.5$$2)$ $\times 10^{-7}$ K$^{–1}$. Approximation dependences of coefficients of linear thermal expansion on temperature have been obtained and reference tables calculated. The data obtained are compared with data from the available literature.
Received: 10.07.2013
English version:
High Temperature, 2014, Volume 52, Issue 4, Pages 536–540
DOI: https://doi.org/10.1134/S0018151X1403016X
Bibliographic databases:
Document Type: Article
UDC: 536.413:553.684
Language: Russian
Citation: Yu. M. Kozlovskiy, S. V. Stankus, “Thermal Expansion of Beryllium Oxide in the Temperature Interval $20$$1550^{\circ}$C”, TVT, 52:4 (2014), 563–567; High Temperature, 52:4 (2014), 536–540
Citation in format AMSBIB
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\paper Thermal Expansion of Beryllium Oxide in the Temperature Interval $20$--$1550^{\circ}$C
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Linking options:
  • https://www.mathnet.ru/eng/tvt621
  • https://www.mathnet.ru/eng/tvt/v52/i4/p563
  • This publication is cited in the following 29 articles:
    1. Yasuhide Mochizuki, Hiroki Koiso, Kaede Nagamatsu, Soungmin Bae, Toshihiro Isobe, Akira Nakajima, “Thermal Properties of the Element and Binary Oxides toward Negative Thermal Expansion: A First-Principles Lattice-Dynamics Study”, J. Phys. Chem. C, 128:1 (2024), 525  crossref
    2. R. N. Abdullaev, R. A. Khairulin, A. Sh. Agazhanov, A. R. Khairulin, Yu. M. Kozlovskii, D. A. Samoshkin, “Plotnost, teplovoe rasshirenie, entalpiya, teploemkost i teploprovodnost kaltsiya v intervale temperatur 720–1290 K”, Žurnal neorganičeskoj himii, 68:2 (2023), 158  crossref
    3. R. N. Abdullaev, R. A. Khairulin, A. Sh. Agazhanov, A. R. Khairulin, Yu. M. Kozlovskii, D. A. Samoshkin, “Density, Thermal Expansion, Enthalpy, Heat Capacity, and Thermal Conductivity of Calcium in the Temperature Range 720–1290 K”, Russ. J. Inorg. Chem., 68:2 (2023), 125  crossref
    4. Rasul N. Abdullaev, Rashid A. Khairulin, Yurii M. Kozlovskii, Sergei V. Stankus, Alibek Sh. Agazhanov, “Density and Thermal Expansion of Magnesium–Calcium Alloys in Solid and Liquid States”, Int J Thermophys, 44:5 (2023)  crossref
    5. Rasul N. Abdullaev, Yurii M. Kozlovskii, Dmitrii A. Samoshkin, Sergei V. Stankus, Alibek Sh. Agazhanov, “Peculiarities of the Eutectic Mg–Li Alloy Thermal Expansion, Heat Capacity and Thermal Conductivity Behavior in the Temperature Range of 80 K to 293 K”, Int J Thermophys, 44:7 (2023)  crossref
    6. Yu. M. Kozlovskii, S. V. Stankus, “Linear thermal expansion coefficient of gallium garnets Gd3Ga5O12, Gd3.04Sc1.8Ga3.16O12, and Ca3Nb1.5Ga3.5O12”, Thermophys. Aeromech., 30:3 (2023), 589  crossref
    7. Bin Cheng, Edward M. Duchnowski, David J. Sprouster, Lance L. Snead, Nicholas R. Brown, Jason R. Trelewicz, “Ceramic composite moderators as replacements for graphite in high temperature microreactors”, Journal of Nuclear Materials, 563 (2022), 153591  crossref
    8. Ming-dong Hou, Xiang-wen Zhou, Bing Liu, “Beryllium oxide utilized in nuclear reactors: Part I: Application history, thermal properties, mechanical properties, corrosion behavior and fabrication methods”, Nuclear Engineering and Technology, 54:12 (2022), 4393  crossref
    9. Agazhanov A.Sh., Samoshkin D.A., Kozlovskii Yu.M., Stankus V S., “Thermal Properties of Arv-U Graphite in the Temperature Interval of 293-1673 K”, Therm. Eng., 68:12 (2021), 953–957  crossref  isi  scopus
    10. Abdullaev R.N., Khairulin R.A., Kozlovskii Yu.M., Stankus S.V., “Density and Thermal Expansion of High Purity Cobalt Over the Temperature Range From 140 K to 2073 K”, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 52:12 (2021), 5449–5456  crossref  isi  scopus
    11. Kozlovskii Yu.M., Stankus V S., “Thermal Expansion of Superconducting Tapes At Low Temperatures”, Thermophys. Aeromechanics, 28:4 (2021), 603–606  crossref  isi  scopus
    12. A Sh Agazhanov, D A Samoshkin, Yu M Kozlovskii, S V Stankus, “Experimental study of the thermophysical properties for aluminum-magnesium alloy AMg3”, J. Phys.: Conf. Ser., 2057:1 (2021), 012101  crossref
    13. Sun H., Zhang R., Wang Ch., Deng J., Tian W., Qiu S., Su G., “Reactivity Feedback Evaluation During the Start-Up of the Heat Pipe Cooled Nuclear Reactors”, Prog. Nucl. Energy, 120 (2020), 103217  crossref  isi  scopus
    14. Kozlovskii Yu.M., Stankus V S., Igumenov I.K., XXXVI Siberian Thermophysical Seminar (Sts 36), Journal of Physics Conference Series, 1677, IOP Publishing Ltd, 2020  crossref  isi  scopus
    15. R N Abdullaev, R A Khairulin, S V Stankus, “Volumetric properties of iron in the solid and liquid states”, J. Phys.: Conf. Ser., 1675:1 (2020), 012087  crossref
    16. Yu. M. Kozlovskii, S. V. Stankus, “Density and thermal expansion of samarium in a wide temperature range”, Thermophys. Aeromechanics, 26:4 (2019), 581–587  crossref  isi  scopus
    17. J. Wei, W. Zhou, S. Li, P. Shen, Sh. Ren, A. Hu, W. Zhou, “Modified embedded atom method potential for modeling the thermodynamic properties of high thermal conductivity beryllium oxide”, ACS Omega, 4:4 (2019), 6339–6346  crossref  isi  scopus
    18. R. N. Abdullaev, R. A. Khairulin, Yu. M. Kozlovskii, A. Sh. Agazhanov, S. V. Stankus, “Density of magnesium and magnesium-lithium alloys in solid and liquid states”, Trans. Nonferrous Met. Soc. China, 29:3 (2019), 507–514  crossref  isi  scopus
    19. D. A. Samoshkin, Yu. M. Kozlovskii, S. V. Stankus, “Experimental study of the titanium nickelide thermophysical properties complex”, XXXV Siberian Thermophysical Seminar, 2019, Journal of Physics Conference Series, 1382, IOP Publishing Ltd, 2019, UNSP 012186  crossref  isi  scopus
    20. Igor Savchenko, Alibek Agazhanov, Dmitrii Samoshkin, D.M. Markovich, P.A. Kuibin, M.A. Vorobyev, “The influence of remanent magnetization on the thermophysical properties of modern magnetically rigid materials”, EPJ Web Conf., 196 (2019), 00052  crossref
    Citing articles in Google Scholar: Russian citations, English citations
    Related articles in Google Scholar: Russian articles, English articles
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