Zamok Luna, Eriksen Janus J
DTU Chemistry, Technical University of Denmark, Kemitorvet Bldg. 206, 2800 Kgs., Lyngby 2800, Denmark.
J Phys Chem A. 2025 Jan 9;129(1):385-395. doi: 10.1021/acs.jpca.4c06651. Epub 2024 Dec 24.
We present a new theory for partitioning simulations of periodic and solid-state systems into physically sound atomic contributions at the level of Kohn-Sham density functional theory. Our theory is based on spatially localized linear combinations of crystalline Gaussian-type orbitals and, as such, capable of exposing local features within periodic electronic structures in a more intuitive and robust manner than alternatives based on the spatial distribution of atomic basis functions alone. Early decomposed cohesive energies of both molecular polymers and different crystalline polymorphs demonstrate how the atomic properties yielded by our theory convincingly align with the expected charge polarization in these systems, also whenever partial charges and Madelung energies may lend themselves somewhat ambiguous to interpretation.
我们提出了一种新理论,可在Kohn-Sham密度泛函理论层面将周期性和固态系统的模拟划分为符合物理原理的原子贡献。我们的理论基于晶体高斯型轨道的空间局域线性组合,因此,与仅基于原子基函数空间分布的其他方法相比,能够以更直观、更稳健的方式揭示周期性电子结构中的局部特征。分子聚合物和不同晶体多晶型物的早期分解内聚能表明,我们的理论所产生的原子性质如何令人信服地与这些系统中预期的电荷极化相一致,即使在部分电荷和马德隆能的解释可能有些模糊的情况下也是如此。
