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On equations of state of nickel and a nickel-aluminum mixture at high pressures
Russian version
R. K. Belkheeva1
1Novosibirsk State University, Novosibirsk, Russia
Email: rimbel@academ.org
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This study describes a method of constructing a Mie-Gruneisen equation of state with a small number of free parameters for nickel. It shows application of this equation of state for describing a behavior of the nickel-aluminum mixture. Porous samples of nickel and the nickel-aluminum mixture are considered as simple thermodynamic-equilibrium mixtures of a condensed substance and gas (air in the pores). Using a logarithmic dependence of the Gruneisen coefficient on a density made it possible to extend a range of applicability of the equations of state into a range of the lower densities. Hugoniot and Poisson adiabats for the nickel samples of various initial porosities and the porous samples of the aluminum-nickel mixture, which are calculated by means of this equation, well agree with experimental data. It is concluded that the proposed equation of state of nickel can be applied for describing the material behavior (including in the mixture with aluminum) under shock compression (not higher than 1 TPa) and isentropic expansion. Keywords: equation of state, parameters of the equation of state, shock adiabat, unloading isentrope, thermodynamic equilibrium, Gruneisen coefficient
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