通过有限一维模型接近集合密度泛函理论中的周期系统

IF 2.9 Q3 CHEMISTRY, PHYSICAL
Remi J Leano, Aurora Pribram-Jones and David A Strubbe
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引用次数: 0

摘要

集合密度泛函理论(EDFT)是基态 DFT 的广义化,它基于系统基态和激发态有限集合的精确形式理论。各种形式的 EDFT 已被证明能提高孤立模型系统、原子和分子中计算能级差的准确性,但目前还不清楚如何利用 EDFT 计算周期性系统的带隙。我们通过估算越来越大的有限一维 "盒中粒子 "系统(接近均匀电子气(UEG))的热力学极限,将 EDFT 的应用扩展到周期性系统。通过使用集合广义哈特里和局部自旋密度近似交换相关函数,我们发现在无限极限中修正为零,正如对金属系统所预期的那样。然而,有效质量存在修正,其结果与其他对一维、二维和三维 UEG 的计算结果相当,这表明 EDFT 有希望在周期性系统上得出非微不足道的结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Approaching periodic systems in ensemble density functional theory via finite one-dimensional models
Ensemble density functional theory (EDFT) is a generalization of ground-state DFT, which is based on an exact formal theory of finite collections of a system’s ground and excited states. EDFT in various forms has been shown to improve the accuracy of calculated energy level differences in isolated model systems, atoms, and molecules, but it is not yet clear how EDFT could be used to calculate band gaps for periodic systems. We extend the application of EDFT toward periodic systems by estimating the thermodynamic limit with increasingly large finite one-dimensional ‘particle in a box’ systems, which approach the uniform electron gas (UEG). Using ensemble-generalized Hartree and local spin density approximation exchange-correlation functionals, we find that corrections go to zero in the infinite limit, as expected for a metallic system. However, there is a correction to the effective mass, with results comparable to other calculations on 1D, 2D, and 3D UEGs, which indicates promise for non-trivial results from EDFT on periodic systems.
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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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