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摘要: 用LMTO法(线性Muffin-Tin轨道法),计算了金属铝的超高压电子结构及零温物态方程。Al的压缩比到10,压力达10 TPa。根据第一原理计算结果,在带结构方面,s带总是处于Fermi能以下,随着压力的增加,s、p和d的带宽增加,随后则杂化程度增加,所以s、d轨道的电子占据数连续变化。上述变化对压力的影响也是连续的,换言之,从sd转变没有理由说明Al在0.5 TPa附近冲击Hugoniot的斜率的拐弯现象。而这一点则是与Altshuler的观点不同。物态方程的第一原理计算结果表明,bcc结构比fcc结构要软,但因差别不很大,即使发生fccbcc的转变,也不会引起Hugoniot的质的变化(拐弯)。Al的LMTO物态方程还表明,我们以前所采用的半经验的冷压误差可达30%。为此,根据LMTO结果,给出新的冷压表达式p=#em/em#=05aii/3,=0/,其中a0=-7.327 79,a1=18.754 3,a2=10.209 7,a3=-2.523 53,a4=-4.787 2,a5=6.065 94,拟合误差小于3%。Abstract: The study for Al up to the pressure p=10 TPa, the compression 0/=10, by using the first principle calculations is performed. The energy band structures and electronic occupation numbers of the states for a series of lattice constants are presented. It follows from the energy band structures that s band always lies below the Fermi level. As the pressure increases, the bandwidths of s, p and d increase, and then the degree of hybridization become higher. So the electronic occupation numbers of s, d orbital change continuously. The effect of above mentioned changes to pressure is continuous too. In other words, sd transition is not the reason for a break in the slope of the shock Hugoniot for Al near 0.5 TPa, as claimed by Altshuler. The equation of state at T=0 K shows that bcc structure is softer than fcc. The results calculated by LMTO are different from the semi-empirical ones given by us previously. A new correct fitting for EOS from the results of LMTO is presented.
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Key words:
- high pressure /
- equation of state /
- electronic structure
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