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Melting Points of Aluminum at Geological Pressures

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Aluminum is a major element inside the Earth's crust constituting about 8% by weight. ... pressure using thermodynamic integration along a pseudo-supercritical path. ... – PowerPoint PPT presentation

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Title: Melting Points of Aluminum at Geological Pressures


1
Melting Points of Aluminum at Geological Pressures
  • Linzey Bachmeier
  • Divesh Bhatt
  • Ilja Siepmann
  • Chemistry Department
  • University of Minnesota

2
Introduction
  • Aluminum is a major element inside the Earths
    crust constituting about 8 by weight. Silicon
    and oxygen are the only two elements more common.
  • To understand aluminums properties inside the
    surface of the Earth requires knowledge of the
    phase behavior under the pressure conditions that
    are present in the crust.
  • This project evaluates one potential energy
    function with respect to its accuracy in
    predicting the solid/liquid phase behavior of
    aluminum at geological pressures.

3
Potential Energy Function
  • The potential energy function that was used
    during this project was the Mei Davenport
    Embedded-Atom(MDEA).
  • U
  • MDEA was originally parameterized to reproduce
    the solid-state properties of aluminum
  • Mei, J. Davenport, J. W. Phys. Rev. B 1992, 46,
    21.

4
Thermodynamics
  • The Gibbs free energy difference between the
    liquid and solid phase is determined at a single
    pressure using thermodynamic integration along a
    pseudo-supercritical path.
  • Also, the Gibbs free energy
  • differences between the two
  • phases is determined at other
  • temperatures using the
  • Multiple Histogram
  • Reweighting (MHR) technique.
  • Grochola, G. J. Chem. Phys. 2004, 120, 2122.
  • Ferrenberg, A. M. Swendsen, R. H. Phys Rev.
    Lett. 1988, 61, 2635.

5
Simulation Details
  • NPT (constant pressure/constant temperature)
    simulations for the face-centered cubic solid and
    the disordered liquid were performed at a few
    different temperatures and many pressures up to
    20 Gpa using the MDEA potential.
  • 256 atoms were used in a three dimensional
    periodic cubic box.
  • Energy-volume and energy-pressure histograms at
    different temperatures and at different pressures
    were combined using MHR, so calculations of the
    Gibbs free energies at different pressures and
    temperatures is allowed.

6
More Simulation Details
  • Subsequently, the melting point as a function of
    pressure, as well as temperature, can be
    determined.
  • For each pressure, a few different temperatures,
    at 50K intervals, were performed.
  • These simulations were done at increasing
    temperatures as the pressure increased in
    anticipation of the melting point of aluminum
    increasing with pressure.

7
Results
  • Explicit thermodynamic integration along a
    pseudo-supercritical path was performed at 850 K
    and 1 atm for the MDEA potential, and the Gibbs
    free energy difference between the solid and
    liquid phase was obtained as 0.11 0.07 kJ/mol.
  • With one Gibbs free energy difference between the
    FCC solid and the liquid phase known, other
    energy differences could be obtained via the MHR
    procedure.

8
Solid-Liquid Gibbs Free Energy Differences
.0001 GPa (1 atm) .001 GPa 1 GPa 2 GPa 5 GPa
850 0.117
900 0.5967 0.5957 -0.0177
950 1.087 0.457 -0.107
1000 0.357
1050 0.817 -0.578
1100 -0.148
9
Results
  • Using the Gibbs free energy differences at each
    of the pressures from the last table and
    reweighting
    histograms at
    different
    temperatures and
    particular
    pressures yields
    the melting point
    at the pressure.

MDEA, 1 GPa
Gs - GL (kJ/mol)
Temperature (K)
10
Results
p Tm (K), MDEA
0.0001 GPa 8387
0.001 GPa 8407
1 GPa 9028
2 GPa 9628
5 GPa 111610
11
Conclusion
  • The Gibbs free energy differences show that the
    solid becomes increasingly more stable relative
    to the liquid at higher temperatures as the
    pressure is increased.
  • With increased stability of the solid phase at
    higher pressure, the melting point increases with
    pressure.

12
Acknowledgments
  • Siepmann Group
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