{"title":"Quantum Density Mechanics: Accurate, purely density-based \\textit{ab initio} implementation of many-electron quantum mechanics","authors":"James C. Ellenbogen","doi":"arxiv-2409.00586","DOIUrl":null,"url":null,"abstract":"This paper derives and demonstrates a new, purely density-based ab initio\napproach for calculation of the energies and properties of many-electron\nsystems. It is based upon the discovery of relationships that govern the\n\"mechanics\" of the electron density -- i.e., relations that connect its\nbehaviors at different points in space. Unlike wave mechanics or prior\nelectron-density-based implementations, such as DFT, this density-mechanical\nimplementation of quantum mechanics involves no many-electron or one-electron\nwave functions (i.e., orbitals). Thus, there is no need to calculate exchange\nenergies, because there are no orbitals to permute or \"exchange\" within\ntwo-electron integrals used to calculate electron-electron repulsion energies.\nIn practice, exchange does not exist within quantum density mechanics. In fact,\nno two-electron integrals need be calculated at all, beyond a single coulomb\nintegral for the 2-electron system. Instead, a \"radius expansion method\" is\nintroduced that permits determination of the two-electron interaction for an\nN-electron system from one with (N-1)-electrons. Also, the method does not rely\nupon a Schrodinger-like equation or the variational method for determination of\naccurate energies and densities. Rather, the above-described results follow\nfrom the derivation and solution of a \"governing equation\" for each number of\nelectrons to obtain a screening relation that connects the behavior at the\n\"tail\" of a one-electron density, to that at the Bohr radius. Solution of these\nequations produces simple expressions that deliver a total energy for a\n2-electron atom that is nearly identical to the experimental value, plus\naccurate energies for neutral 3, 4, and 5-electron atoms, along with accurate\none-electron densities of these atoms. Further, these methods scale in\ncomplexity only as N, not as a power of N, as do most other accurate\nmany-electron methods.","PeriodicalId":501304,"journal":{"name":"arXiv - PHYS - Chemical Physics","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - PHYS - Chemical Physics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2409.00586","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
This paper derives and demonstrates a new, purely density-based ab initio
approach for calculation of the energies and properties of many-electron
systems. It is based upon the discovery of relationships that govern the
"mechanics" of the electron density -- i.e., relations that connect its
behaviors at different points in space. Unlike wave mechanics or prior
electron-density-based implementations, such as DFT, this density-mechanical
implementation of quantum mechanics involves no many-electron or one-electron
wave functions (i.e., orbitals). Thus, there is no need to calculate exchange
energies, because there are no orbitals to permute or "exchange" within
two-electron integrals used to calculate electron-electron repulsion energies.
In practice, exchange does not exist within quantum density mechanics. In fact,
no two-electron integrals need be calculated at all, beyond a single coulomb
integral for the 2-electron system. Instead, a "radius expansion method" is
introduced that permits determination of the two-electron interaction for an
N-electron system from one with (N-1)-electrons. Also, the method does not rely
upon a Schrodinger-like equation or the variational method for determination of
accurate energies and densities. Rather, the above-described results follow
from the derivation and solution of a "governing equation" for each number of
electrons to obtain a screening relation that connects the behavior at the
"tail" of a one-electron density, to that at the Bohr radius. Solution of these
equations produces simple expressions that deliver a total energy for a
2-electron atom that is nearly identical to the experimental value, plus
accurate energies for neutral 3, 4, and 5-electron atoms, along with accurate
one-electron densities of these atoms. Further, these methods scale in
complexity only as N, not as a power of N, as do most other accurate
many-electron methods.
这篇论文推导并演示了一种新的、纯粹基于密度的 ab initio 方法,用于计算多电子系统的能量和性质。该方法基于对电子密度 "力学 "关系的发现,即在空间不同点上连接电子密度行为的关系。与波动力学或基于前电子密度的实现(如 DFT)不同,量子力学的这种密度力学实现不涉及多电子或单电子波函数(即轨道)。因此,不需要计算交换能,因为在用于计算电子-电子斥力能的双电子积分中,没有轨道可以排列或 "交换"。实际上,除了计算双电子系统的单一库仑积分之外,根本不需要计算双电子积分。取而代之的是一种 "半径扩展法",它允许从一个有(N-1)个电子的系统中确定一个 N 电子系统的双电子相互作用。此外,该方法并不依赖于类似薛定谔方程或变分法来确定精确的能量和密度。相反,上述结果源于对每个电子数的 "支配方程 "的推导和求解,从而获得一种屏蔽关系,将单电子密度 "尾部 "的行为与玻尔半径的行为联系起来。求解这些方程可以得到简单的表达式,从而得到与实验值几乎相同的 2 电子原子的总能量,以及中性 3、4 和 5 电子原子的精确能量和这些原子的精确单电子密度。此外,这些方法的不复杂度仅以 N 为标度,而不是以 N 的幂为标度,这一点与其他大多数精确的单电子学方法相同。