Chin. Phys. Lett.  2000, Vol. 17 Issue (4): 279-281    DOI:
Original Articles |
A Molecular Dynamics Simulation of CaSiO3 Melt Under an Electric Field
HUANG Shi-Ping1;YOU Jing-Pin1;JIANG Guo-Chang1;F. Yoshida2;XU Kuang-Di1
1Shanghai Enhanced Laboratory of Ferro-metallurgy, Shanghai University, Shanghai 200072 2Department of Physics, Shiga University of Medical Science, Shiga 520-2192, Japan
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HUANG Shi-Ping, YOU Jing-Pin, JIANG Guo-Chang et al  2000 Chin. Phys. Lett. 17 279-281
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Abstract The results of a molecular dynamics (MD) simulation are presented for CaSiO3 melt under an electric field. The two-body interaction potential is adopted in the simulation, with parameters chosen so that the calculated static structure is consistent with results of high temperature x-ray experiments. It is found that the MD results for the heat capacity at constant volume, the self-diffusion coefficient and the electrical conductivity change greatly when the electric field is over 500 MV/m. Discussion is given on these results, together with the frequency-dependent electrical conductivity.
Keywords: 61.20.Ja      61.20.Qg     
Published: 01 April 2000
PACS:  61.20.Ja (Computer simulation of liquid structure)  
  61.20.Qg (Structure of associated liquids: electrolytes, molten salts, etc.)  
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HUANG Shi-Ping
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