2016年第63回応用物理学会春季学術講演会

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一般セッション(口頭講演)

1 応用物理学一般 » 1.1 応用物理一般・学際領域

[20a-S322-1~8] 1.1 応用物理一般・学際領域

2016年3月20日(日) 10:15 〜 12:15 S322 (南3号館)

藤川 知栄美(東海大)

11:15 〜 11:30

[20a-S322-5] Understanding the Difference in Cohesive Energies between Alpha and Beta Tin

Manzhos Sergei1、Legrain Fleur1、Malyi Oleksandr2、Persson Clas2 (1.Ntl Uni of Singapore、2.Uni of Oslo)

キーワード:tin,phase transition,ab initio modeling

The transition temperature between the low-temperature alpha phase of tin to beta tin is close to the room temperature (Ttrans =130C), and the difference in cohesive energy of the two phases at 0 K of about dEcoh=0.02 eV/atom is at the limit of the accuracy of DFT (density functional theory) with available exchange-correlation functionals. It is however critically important to model the relative phase energies correctly for any reasonable description of phenomena and technologies involving these phases, for example, the performance of tin electrodes in electrochemical batteries. Here, we show that several commonly used and converged DFT setups using the most practical and widely used PBE functional result in dEcoh≈0.04 eV/atom, with different types of basis sets and with different models of core electrons (all-electron or pseudopotentials of different types), which leads to a significant overestimation of Ttrans. We show that this error is due to the errors in relative positions of s and p –like bands, which, combined with different populations of these bands in alpha and beta Sn, leads to overstabilization of alpha tin. We show that this error can be effectively corrected by applying a Hubbard +U correction to s –like states, whereby correct cohesive energies of both alpha and beta Sn can be obtained with the same computational scheme. We quantify for the first time the effects of anharmonicity on dEcoh and find that it is negligible.