Tkatchenko-Scheffler method with iterative Hirshfeld partitioning: Difference between revisions

The Tkatchenko-Scheffler method, which uses fixed neutral atoms as a reference to estimate the effective volumes of atoms-in-molecule (AIM) and to calibrate their polarizabilities and dispersion coefficients, fails to describe the structure and the energetics of ionic solids. As shown in references ^[1] and ^[2], this problem can be solved by replacing the conventional Hirshfeld partitioning used to compute properties of interacting atoms by the iterative scheme proposed by Bultinck^[3]. In this iterative Hirshfeld algorithm (HI), the neutral reference atoms are replaced with ions with fractional charges determined together with the AIM charge densities in a single iterative procedure. The algorithm is initialized with a promolecular density defined by non-interacting neutral atoms. The iterative procedure then runs in the following steps:

• The Hirshfeld weight function for the step ${\displaystyle i}$ is computed as

${\displaystyle w_A^{i}({\mathbf{r}}) = {n^{i}_A({\mathbf{r}})}/\left({\sum_B n^{i}_B({\mathbf{r}})}\right)}$

where the sum extends over all atoms in the system.

• The number of electrons per atom is determined using

${\displaystyle N_{A}^{i+1} = N_{A}^{i} + \int \left[ n_{A}^{i}(\mathbf{r}) - w_{A}^i(\mathbf{r})\,n(\mathbf{r}) \right]\,d^{3}\mathbf{r}.}$

• New reference charge densities are computed using

${\displaystyle n^{i+1}_A(\mathbf{r}) = n^{\text{lint}(N^i_A)}(\mathbf{r})\left [ \text{uint}(N^i_A)-N^i_A\right ] + n^{\text{uint}(N_A^i)}({\mathbf{r}})\left [ N^i_A - \text{lint}(N^i_A)\right ]}$

where ${\displaystyle \text{lint}(x)}$ expresses the integer part of ${\displaystyle x}$ and ${\displaystyle \text{uint}(x)=\text{lint}(x)+1}$.

Steps (1) to (3) are iterated until the difference in the electronic populations between two subsequent steps (${\displaystyle \Delta_{A}^{i} = \vert N_{A}^{i}-N_{A}^{i+1}\vert}$) is less than a predefined threshold for all atoms. The converged iterative Hirshfeld weights (${\displaystyle w_{A}^{i}}$) are then used to define the AIM properties needed to evaluate the dispersion energy (see Tkatchenko-Scheffler method).

The Tkatchenko-Scheffler method with iterative Hirshfeld partitioning (TS-HI) is invoked by setting IVDW=21. The convergence criterion for iterative Hirshfeld partitioning (in e) can optionally be defined via the parameter HITOLER (the default value is 5e-5). Other optional parameters controlling the input for the calculation are as in the conventional Tkatchenko-Scheffler method. The default value of the adjustable parameter VDW_SR is 0.95 and corresponds to the PBE functional.

The TS-HI method is described in detail in reference ^[1] and its performance in optimization of various crystalline systems is examined in reference ^[2].

Related tags and articles

HITOLER, VDW_SR, VDW_ALPHA, VDW_C6, VDW_R0, VDW_S6, VDW_D, LVDW_EWALD, IVDW, Tkatchenko-Scheffler method, Self-consistent screening in Tkatchenko-Scheffler method, Many-body dispersion energy, Many-body dispersion energy with fractionally ionic model for polarizability

References