Add to ORKG444-447Melting curves representing the variations of melting temperature <i style="mso-bidi-font-style: normal">Tm with pressure P have been determined for sixteen alkali halides. The calculations have been performed using Lindemann-Gilvarry law for melting along with an expression for the volume dependence of the Grüneisen parameter. The formulation thus developed can be used to predict melting temperatures for materials at high pressures. It is found that the melting temperature increases with pressure in a non-linear manner such that the slope dTm/dP decreases continuously with the increase in pressure
The motivation for the present study is to be found in the recent experiments of Fuchizaki and Hamay...
The Lindemann law and the extension of the finite strain expansion of the Mie-Grüneisen equation to ...
Melting temperatures of alkali halides have been calculated assuming that different structures of an...
In this work, based on the Lindemann's formula of melting and the pressure-dependent Grüneisen param...
For the better general understanding of melting behavior at high pressure, we investigated the influ...
387-397The thermoelastic properties of materials at high temperatures, specifically the thermal ex...
An experimental and theoretical study of premelting behaviour and mechanisms of melting in the alkal...
Accurate prediction of fundamental properties such as melting points using direct physical simulatio...
The relations between pair potentials and melting curves at high pressures are inves-tigated and the...
For the better general understanding of melting behavior at high pressure, we investigated the influ...
AbstractIn the present work, the non-inverted (isothermal) type equations of state (EOS) which are b...
Utilising the abeolute critical temperature (Tc) data for maids of high melting points, as recorded ...
A melting criterion for binary ionic compounds is formulated in terms of an instability due to the o...
368-371Following the assumption of Jeanloz and Anderson, a computing model for the pressure dependen...
917-918The melting temperature, Tm, is calculated in the pressure range of 0.2-185.0 kbars in case...
The motivation for the present study is to be found in the recent experiments of Fuchizaki and Hamay...
The Lindemann law and the extension of the finite strain expansion of the Mie-Grüneisen equation to ...
Melting temperatures of alkali halides have been calculated assuming that different structures of an...
In this work, based on the Lindemann's formula of melting and the pressure-dependent Grüneisen param...
For the better general understanding of melting behavior at high pressure, we investigated the influ...
387-397The thermoelastic properties of materials at high temperatures, specifically the thermal ex...
An experimental and theoretical study of premelting behaviour and mechanisms of melting in the alkal...
Accurate prediction of fundamental properties such as melting points using direct physical simulatio...
The relations between pair potentials and melting curves at high pressures are inves-tigated and the...
For the better general understanding of melting behavior at high pressure, we investigated the influ...
AbstractIn the present work, the non-inverted (isothermal) type equations of state (EOS) which are b...
Utilising the abeolute critical temperature (Tc) data for maids of high melting points, as recorded ...
A melting criterion for binary ionic compounds is formulated in terms of an instability due to the o...
368-371Following the assumption of Jeanloz and Anderson, a computing model for the pressure dependen...
917-918The melting temperature, Tm, is calculated in the pressure range of 0.2-185.0 kbars in case...
The motivation for the present study is to be found in the recent experiments of Fuchizaki and Hamay...
The Lindemann law and the extension of the finite strain expansion of the Mie-Grüneisen equation to ...
Melting temperatures of alkali halides have been calculated assuming that different structures of an...