利用操纵电子-电子库仑积分上的耦合强度参数求解非相对论电子Schrödinger方程

arXiv: Chemical Physics Pub Date : 2019-08-16 DOI:10.26434/chemrxiv.9638810

S. Kristyán

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引用次数: 0

摘要

非相对论性电子哈密顿量H(a)= Hkin+Hne+aHee，扩展了耦合强度参数(a)，允许开关电子-电子排斥能量。首先求解比较简单的a=0情况，然后由此生成真实的(物理的)a=1情况的解，计算主要针对基态(K=0)的总电子能量(Etotal electrr,K)。该策略是利用广义Moller-Plesset (MP)、哈密顿平方(H2)和配置相互作用(CI)器件实现的。对哈密顿矩阵应用标准特征求解器(一次或两次)，消除了算法收敛自洽域的需要，并对基集误差和相关效应进行了校正。(SCF收敛通常在标准的HF-SCF/basis/a=1例程中执行。)

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Solving the Non-Relativistic Electronic Schrödinger Equation with Manipulating the Coupling Strength Parameter over the Electron-Electron Coulomb Integrals

The non-relativistic electronic Hamiltonian, H(a)= Hkin+Hne+aHee, extended with coupling strength parameter (a), allows to switch the electron-electron repulsion energy off and on. First, the easier a=0 case is solved and the solution of real (physical) a=1 case is generated thereafter from it to calculate the total electronic energy (Etotal electr,K) mainly for ground state (K=0). This strategy is worked out with utilizing generalized Moller-Plesset (MP), square of Hamiltonian (H2) and Configuration interactions (CI) devices. Applying standard eigensolver for Hamiltonian matrices (one or two times) buys off the needs of self-consistent field (SCF) convergence in this algorithm, along with providing the correction for basis set error and correlation effect. (SCF convergence is typically performed in the standard HF-SCF/basis/a=1 routine in today practice.)

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arXiv: Chemical Physics

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