Ionization energy: sd transfer error and Perdew-Zunger self-interaction correction energy penalty in 3d atoms

Rohan Maniar, Priyanka B. Shukla, J. Karl Johnson, Koblar A. Jackson, John P. Perdew
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Abstract

To accurately describe the energetics of transition metal systems, density functional approximations (DFAs) must provide a balanced description of s- and d- electrons. One measure of this is the sd transfer error, which has previously been defined as $E(\mathrm{3d}^{n-1} \mathrm{4s}^1) -E(\mathrm{3d}^{n-2} \mathrm{4s}^2)$. Theoretical concerns have been raised on the validity of these results owing to the evaluation of excited-state energies using ground-state DFAs. A more serious concern appears to be strong correlations in the $\mathrm{4s}^2$ configuration. Here we define a ground-state measure of the sd transfer error, based on the errors of s- and d-electron second ionization energies of the atoms, that effectively circumvents the aforementioned problems. We find an improved performance as we move from LSDA to PBE to r$^2$SCAN for first-row transition metal atoms. However, we found large (~ 2 eV) ground-state sd transfer errors when applying a Perdew-Zunger self-interaction correction. This is attributed to an "energy penalty" associated with the noded 3d orbitals. A local scaling of the self-interaction correction to LSDA results in a cancellation of s- and d-errors.
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电离能:3d 原子中的 sd 转移误差和 Perdew-Zunger 自相互作用修正能量惩罚
为了准确描述过渡金属体系的能量学,密度函数近似(DFA)必须平衡地描述s电子和d电子。其中一个衡量标准是 sd 转移误差,以前的定义是 $E(\mathrm{3d}^{n-1}\mathrm{4s}^1)-E(\mathrm{3d}^{n-2}\mathrm{4s}^2)$。由于使用基态 DFA 评估激发态能量,这些结果的有效性引起了理论界的关注。一个更严重的问题似乎是$\mathrm{4s}^2$构型中的强相关性。在此,我们根据原子的 s 电子和 d 电子二次电离能的误差,定义了 sd 转移误差的基态测量方法,从而有效地避免了上述问题。我们发现,从 LSDA 到 PBE 再到 r$^2$SCAN,第一排过渡金属原子的性能有所改善。然而,当应用 Perdew-Zunger 自相互作用校正时,我们发现地面状态 sd 转移误差较大(约 2 eV)。这归因于与有节 3d 轨道相关的 "能量惩罚"。对 LSDA 的自作用校正进行局部缩放,可以消除 s 和 d 误差。
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