Abstract
The unified analytic melt-shear model that we introduced a decade ago is generalized to multi-phase materials. A new scheme for calculating the values of the model parameters for both the cold ( T = 0 ) shear modulus ( G ) and the melting temperature at all densities ( ρ ) is developed. The generalized melt-shear model is applied to molybdenum, a multi-phase material with a body-centered cubic (bcc) structure at low ρ which loses its dynamical stability with increasing pressure (P) and is therefore replaced by another (dynamically stable) solid structure at high ρ . One of the candidates for the high- ρ structure of Mo is face-centered cubic (fcc). The model is compared to (i) our ab initio results on the cold shear modulus of both bcc-Mo and fcc-Mo as a function of ρ , and (ii) the available theoretical results on the melting of bcc-Mo and our own quantum molecular dynamics (QMD) simulations of one melting point of fcc-Mo. Our generalized model of G ( ρ , T ) is used to calculate the shear modulus of bcc-Mo along its principal Hugoniot. It predicts that G of bcc-Mo increases with P up to ∼240 GPa and then decreases at higher P. This behavior is intrinsic to bcc-Mo and does not require the introduction of another solid phase such as Phase II suggested by Errandonea et al. Generalized melt-shear models for Ta and W also predict an increase in G followed by a decrease along the principal Hugoniot, hence this behavior may be typical for transition metals with ambient bcc structure that dynamically destabilize at high P. Thus, we concur with the conclusion reached in several recent papers (Nguyen et al., Zhang et al., Wang et al.) that no solid-solid phase transition can be definitively inferred on the basis of sound velocity data from shock experiments on Mo. Finally, our QMD simulations support the validity of the phase diagram of Mo suggested by Zeng et al.
Highlights
Unified Analytic Melt-Shear ModelA reliable model of the adiabatic shear modulus ( G ) of a polycrystalline solid at all temperatures from zero to close to Tm, the melting temperature, and up to pressures ( P) of order100 GPa is needed for many applications, including the modeling of plastic deformation at extremes of pressure and temperature, numerical calculations of elastic and shock wave propagation, and even calculations of the oscillations of low-mass astrophysical objects
Our ab initio study of the thermoelasticity of Mo described below resulted in a T = 0 shear modulus for bcc-Mo that is described by the following equation (G in GPa, ρ in g/cm3 ): G (ρ, 0) = 113.0 + 33.5 (ρ − 10.25) + 4.65 (ρ − 10.25)2 − 0.68 (ρ − 10.25)3 + 0.018 (ρ − 10.25)4
In the following we present the results of our calculations of the T = 0 shear moduli of both bcc-Mo and fcc-Mo, as well as the finite-T shear modulus of bcc-Mo using the density functional theory (DFT) code VASP
Summary
A reliable model of the adiabatic (isentropic) shear modulus ( G ) of a polycrystalline solid at all temperatures from zero to close to Tm , the melting temperature, and up to pressures ( P) of order. In 2003–2004 we developed a unified analytic model for the melting temperature as a function of density, Tm (ρ), and the density-temperature dependence of the shear modulus, G (ρ, T ), at all densities and 0 ≤ T ≤ Tm [1,2]. Equations (2), (4), and (5) constitute our unified model of Tm (ρ) and G (ρ, T ) for single-phase metals. For polymorphic (multi-phase) metals, the γ1 -γ2 -q values for the ambient solid structure may differ significantly from those for the high-P structure(s), and the model may fail in its description of those high-P structure(s). We generalize our unified melt-shear model to polymorphic materials. We shall explain how such envelopes are constructed, and demonstrate the fidelity of the generalized model using molybdenum as an example
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