Open AccessFirst-principles molecular-dynamics simulation of liquid rubidium under high pressures
Author(s) -
Fuyuki Shimojo,
Y. Zempo,
Kozo Hoshino,
Mitsuo Watabe
Publication year - 1997
Publication title -
physical review. b, condensed matter
Language(s) - English
Resource type - Journals
eISSN - 1095-3795
pISSN - 0163-1829
DOI - 10.1103/physrevb.55.5708
Subject(s) - rubidium , component (thermodynamics) , molecular dynamics , materials science , compression (physics) , triple point , condensed matter physics , range (aeronautics) , pair distribution function , thermodynamics , atomic physics , physics , quantum mechanics , potassium , metallurgy , composite material
The effects of compression on the structural and electronic properties of liquid rubidium are studied along the melting curve by means of a first-principles molecular-dynamics simulation. It is shown that the calculated pair distribution functions g(r) are in good agreement with the experimental results for a wide range of pressures; the liquid rubidium is compressed uniformly at 2.5 GPa, and there exist some deviations from the uniform compression at 6.1 GPa. This structural change to a denser state is related to an electronic s-d transition in the liquid state. It is found that, near the triple point, the electronic density of states consists mostly of the s component and, with increasing pressure, the s component decreases gradually over a wide range of energy, and the d component near the Fermi level increases. @S0163-1829~97!06509-0#
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