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TVT, 2016, Volume 54, Issue 5, Pages 716–723 (Mi tvt8730)  

This article is cited in 9 scientific papers (total in 9 papers)

Thermophysical Properties of Materials

Modeling shock loading of multicomponent materials including bismuth

S. A. Kinelovskiiab, K. K. Maevskiiab

a Lavrentyev Institute of Hydrodynamics of Siberian Branch of the Russian Academy of Sciences, Novosibirsk
b Novosibirsk State University

Abstract: The behavior of multicomponent mixtures and alloys, including bismuth, under high dynamic loads is described by the thermodynamically equilibrium (TEC) model. For condensed phases, the Mie–Grüneisen-type equation of state with regard to the Grüneisen coefficient depending on temperature is used, and gas in pores is among the main environmental components. The model used makes it possible to calculate the behavior of bismuth and materials based on this element (mixtures and alloys) for pressures higher than $6$ GPa in one-velocity and one-temperature approximations on the assumption that the pressure is identical for all phases. The calculation results have been compared with the known experimental data and the model calculations performed by different researchers for porosity values varying from $1$ to $3$. It has been indicated that the model reliably describes shock loading of solid and porous bismuth as well as multicomponent alloys containing bismuth.

Funding Agency Grant Number
Russian Foundation for Basic Research 13-03-00663
This work was supported in part by the Russian Foundation for Basic Research, project no. 13-03-00663.


DOI: https://doi.org/10.7868/S0040364416050161

Full text: PDF file (605 kB)
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English version:
High Temperature, 2016, 54:5, 675–681

Bibliographic databases:

UDC: 534.222.2+546.87
Received: 27.01.2015
Accepted:13.10.2015

Citation: S. A. Kinelovskii, K. K. Maevskii, “Modeling shock loading of multicomponent materials including bismuth”, TVT, 54:5 (2016), 716–723; High Temperature, 54:5 (2016), 675–681

Citation in format AMSBIB
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\paper Modeling shock loading of multicomponent materials including bismuth
\jour TVT
\yr 2016
\vol 54
\issue 5
\pages 716--723
\mathnet{http://mi.mathnet.ru/tvt8730}
\crossref{https://doi.org/10.7868/S0040364416050161}
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\transl
\jour High Temperature
\yr 2016
\vol 54
\issue 5
\pages 675--681
\crossref{https://doi.org/10.1134/S0018151X16050163}
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    Citing articles on Google Scholar: Russian citations, English citations
    Related articles on Google Scholar: Russian articles, English articles

    This publication is cited in the following articles:
    1. I. V. Lomonosov, S. V. Fortova, “Wide-range semiempirical equations of state of matter for numerical simulation on high-energy processes”, High Temperature, 55:4 (2017), 585–610  mathnet  crossref  crossref  isi  elib
    2. K. K. Maevskii, “Numerical investigations of oxides and silicates under shock-wave loading”: A. Chesnokov, E. Pruuel, V. Shelukhin, All-Russian Conference With International Participation Modern Problems of Continuum Mechanics and Explosion Physics Dedicated to the 60th Anniversary of Lavrentyev Institute of Hydrodynamics SB RAS, Journal of Physics Conference Series, 894, IOP Publishing Ltd, 2017, UNSP 012057  crossref  isi  scopus
    3. K. K. Maevskii, S. A. Kinelovskii, “Thermodynamic parameters of oxides by the example of periclase in representations of the equilibrium model”, Proceedings of the International Conference on Advanced Materials With Hierarchical Structure For New Technologies and Reliable Structures 2017 (AMHS'17), AIP Conf. Proc., 1909, eds. V. Panin, S. Psakhie, V. Fomin, Amer. Inst. Phys., 2017, UNSP 020127  crossref  isi  scopus
    4. S. A. Kinelovskii, K. K. Maevskii, “Thermodynamic parameters of mixtures with allowance for phase transition components under shock-wave loading”, Epitoanyag, 69:1 (2017), 29–32  crossref  isi
    5. S. A. Kinelovskii, K. K. Maevskii, “Thermodynamic parameters of mixtures with allowance for phase transition components under shock-wave loading”, 4th International Conference on Competitive Materials and Technology Processes (IC-CMTP4), IOP Conference Series-Materials Science and Engineering, 175, IOP Publishing Ltd, 2017, UNSP 012030  crossref  isi  scopus
    6. F. I. Abbas, G. M. Bhuiyan, M. R. Kasem, “A study of thermodynamics of mixing for Al$_{1-x}$Sn$_x$ liquid binary alloy”, J. Non-Cryst. Solids, 481 (2018), 391–396  crossref  isi  scopus
    7. K. K. Maevskii, “Numerical simulation of thermodynamic parameters of lithium deuteride and its mixtures under shock wave loading”, Advanced Materials With Hierarchical Structure For New Technologies and Reliable Structures, AIP Conf. Proc., 2051, eds. V. Panin, S. Psakhie, V. Fomin, Amer. Inst. Phys., 2018, UNSP 020181  crossref  isi  scopus
    8. K. K. Maevskii, S. A. Kinelovskii, “Thermodynamic parameters of mixtures with epoxy as a component under shock wave loading”, XXXII International Conference on Interaction of Intense Energy Fluxes With Matter (Elbrus 2017), Journal of Physics Conference Series, 946, IOP Publishing Ltd, 2018, UNSP 012113  crossref  isi  scopus
    9. K. K. Maevskii, “Thermodynamic parameters of lithium deuteride in pressure range 5-1000 gigapascals”, Math. Montisnigri, 41 (2018), 123–130  isi
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