DFT-D2: Difference between revisions
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In the D2 method of Grimme | In the DFT-D2 method of Grimme{{cite|grimme:jcc:06}}, the correction term takes the form: | ||
<math>E_{\mathrm{disp}} = -\frac{1}{2} \sum_{i=1}^{N_{at}} \sum_{j=1}^{N_{at}} \sum_{\mathbf{L}} {}^{\prime} \frac{C_{6ij}}{r_{ij,L}^{6}} f_{d,6}({r}_{ij,L}) </math> | :<math>E_{\mathrm{disp}} = -\frac{1}{2} \sum_{i=1}^{N_{at}} \sum_{j=1}^{N_{at}} \sum_{\mathbf{L}} {}^{\prime} \frac{C_{6ij}}{r_{ij,L}^{6}} f_{d,6}({r}_{ij,\mathbf{L}}) </math> | ||
where the summations are over all | where the first two summations are over all <math>N_{at}</math> atoms in the unit cell and the third summation is over all translations of the unit cell <math>{\mathbf{L}}=(l_1,l_2,l_3)</math> where the prime indicates that <math>i\not=j</math> for <math>{\mathbf{L}}=0</math>. <math>C_{6ij}</math> denotes the dispersion coefficient for the atom pair <math>ij</math>, <math>{r}_{ij,\mathbf{L}}</math> is the distance between atom <math>i</math> located in the reference cell <math>\mathbf{L}=0</math> and atom <math>j</math> in the cell <math>L</math> and the term <math>f(r_{ij})</math> is a damping function whose role is to scale the force field such as to minimize the contributions from interactions within typical bonding distances. In practice, the terms in the equation for <math>E_{\mathrm{disp}}</math> corresponding to interactions over distances longer than a certain suitably chosen cutoff radius ({{TAG|VDW_RADIUS}}, see below) contribute only negligibly to <math>E_{\mathrm{disp}}</math> and can be ignored. Parameters <math>C_{6ij}</math> and <math>R_{0ij}</math> are computed using the following combination rules: | ||
<math>C_{6ij} = \sqrt{C_{6ii} C_{6jj}}</math> | :<math>C_{6ij} = \sqrt{C_{6ii} C_{6jj}}</math> | ||
and | and | ||
<math>R_{0ij} = R_{0i}+ R_{0j}. </math> | :<math>R_{0ij} = R_{0i}+ R_{0j}. </math> | ||
The values for <math>C_{6ii}</math> and <math>R_{0i}</math> are tabulated for each element and are insensitive to the particular chemical situation (for instance, <math>C_6</math> for carbon in methane takes exactly the same value as that for C in benzene within this approximation). In the | The values for <math>C_{6ii}</math> and <math>R_{0i}</math> are tabulated for each element and are insensitive to the particular chemical situation (for instance, <math>C_6</math> for carbon in methane takes exactly the same value as that for C in benzene within this approximation). In the DFT-D2 method, a Fermi-type damping function is used: | ||
<math>f_{d,6}(r_{ij}) = \frac{s_6}{1+e^{-d(r_{ij}/(s_R\,R_{0ij})-1)}}</math> | :<math>f_{d,6}(r_{ij}) = \frac{s_6}{1+e^{-d(r_{ij}/(s_R\,R_{0ij})-1)}}</math> | ||
whereby the global scaling parameter <math>s_6</math> has been optimized for several different DFT functionals such as PBE (<math>s_6=0.75</math>), BLYP (<math>s_6=1.2</math>) | whereby the global scaling parameter <math>s_6</math> has been optimized for several different DFT functionals such as PBE (<math>s_6=0.75</math>), BLYP (<math>s_6=1.2</math>) or B3LYP (<math>s_6=1.05</math>). The parameter <math>s_R</math> is usually fixed at 1.00. The DFT-D2 method can be activated by setting {{TAG|IVDW}}=''1|10'' or by specifying {{TAG|LVDW}}=''.TRUE.'' (this parameter is obsolete as of VASP.5.3.3). Optionally, the damping function and the vdW parameters can be controlled using the following flags (the given values are the default ones): | ||
*{{TAG|VDW_RADIUS}}=50.0 cutoff radius (in <math>\AA</math>) for pair interactions | *{{TAG|VDW_RADIUS}}=50.0 : cutoff radius (in <math>\AA</math>) for pair interactions | ||
*{{TAG|VDW_S6}}=0.75 global scaling factor <math>s_6</math> (available in VASP.5.3.4 and later) | *{{TAG|VDW_S6}}=0.75 : global scaling factor <math>s_6</math> (available in VASP.5.3.4 and later) | ||
*{{TAG|VDW_SR}}=1.00 scaling factor <math>s_R</math> (available in VASP.5.3.4 and later) | *{{TAG|VDW_SR}}=1.00 : scaling factor <math>s_R</math> (available in VASP.5.3.4 and later) | ||
*{{TAG|VDW_SCALING}}=0.75 the same as {{TAG|VDW_S6}} (obsolete as of VASP.5.3.4) | *{{TAG|VDW_SCALING}}=0.75 : the same as {{TAG|VDW_S6}} (obsolete as of VASP.5.3.4) | ||
*{{TAG|VDW_D}}=20.0 damping parameter <math>d</math> | *{{TAG|VDW_D}}=20.0 : damping parameter <math>d</math> | ||
*{{TAG|VDW_C6}}=[real array] <math>C_6</math> parameters (<math>\mathrm{Jnm}^{6}\mathrm{mol}^{-1}</math>) for each species defined in the {{TAG|POSCAR}} file | *{{TAG|VDW_C6}}=[real array] : <math>C_6</math> parameters (<math>\mathrm{Jnm}^{6}\mathrm{mol}^{-1}</math>) for each species defined in the {{TAG|POSCAR}} file | ||
*{{TAG|VDW_R0}}=[real array] <math>R_0</math> parameters (<math>\AA</math>) for each species defined in the {{TAG|POSCAR}} file | *{{TAG|VDW_R0}}=[real array] : <math>R_0</math> parameters (<math>\AA</math>) for each species defined in the {{TAG|POSCAR}} file | ||
*{{TAG|LVDW_EWALD}}=''.FALSE.'' | *{{TAG|LVDW_EWALD}}=''.FALSE.'' : the lattice summation in <math>E_{\mathrm{disp}}</math> expression is computed by means of Ewald's summation (''.TRUE.'' ) or via a real space summation over all atomic pairs within cutoff radius {{TAG|VDW_RADIUS}} (''.FALSE.''). (available in VASP.5.3.4 and later) | ||
The performance of PBE-D2 method in optimization of various crystalline systems has been tested systematically in reference | The performance of PBE-D2 method in optimization of various crystalline systems has been tested systematically in reference {{cite|bucko:jpca:10}}. | ||
{{NB|important|It is recommended to use the more advanced and more accurate method {{TAG|DFT-D3}}.{{cite|grimme:jcp:10}}}} | |||
{{NB|mind| | |||
*The defaults for {{TAG|VDW_C6}} and {{TAG|VDW_R0}} are defined only for elements in the first five rows of the periodic table (i.e. H-Xe). If the system contains other elements the user has to define these parameters in {{TAG|INCAR}}. | |||
*The defaults for parameters controlling the damping function ({{TAG|VDW_S6}}, {{TAG|VDW_SR}}, {{TAG|VDW_D}}) are available for the PBE ({{TAG|GGA}}{{=}}PE), BP, revPBE, PBE0, TPSS, and B3LYP functionals. If any other functional is used in a DFT-D2 calculation, the value of {{TAG|VDW_S6}} (or {{TAG|VDW_SCALING}} in versions before VASP.5.3.4) has to be defined in {{TAG|INCAR}}. | |||
*As of VASP.5.3.4, the default value for {{TAG|VDW_RADIUS}} has been increased from 30 to 50 <math>\AA</math>. | *As of VASP.5.3.4, the default value for {{TAG|VDW_RADIUS}} has been increased from 30 to 50 <math>\AA</math>. | ||
*Ewald's summation in the calculation of <math>E_{\mathrm{disp}}</math> calculation (controlled via {{TAG|LVDW_EWALD}}) is implemented according to reference {{cite|kerber:jcc:08}} and is available as of VASP.5.3.4.}} | |||
== Related tags and articles == | |||
{{TAG|VDW_RADIUS}}, | |||
{{TAG|VDW_S6}}, | |||
{{TAG|VDW_SR}}, | |||
{{TAG|VDW_SCALING}}, | |||
{{TAG|VDW_D}}, | |||
{{TAG|VDW_C6}}, | |||
{{TAG|VDW_R0}}, | |||
{{TAG|LVDW_EWALD}}, | |||
{{TAG|IVDW}}, | {{TAG|IVDW}}, | ||
{{TAG| | {{TAG|DFT-ulg}}, | ||
{{TAG|DFT-D3}}, | {{TAG|DFT-D3}}, | ||
[[DFT-D4]] | |||
== References == | |||
<references/> | |||
---- | ---- | ||
[[ | [[Category:Exchange-correlation functionals]][[Category:van der Waals functionals]][[Category:Theory]] | ||
[[Category: |
Latest revision as of 20:14, 13 June 2024
In the DFT-D2 method of Grimme[1], the correction term takes the form:
where the first two summations are over all atoms in the unit cell and the third summation is over all translations of the unit cell where the prime indicates that for . denotes the dispersion coefficient for the atom pair , is the distance between atom located in the reference cell and atom in the cell and the term is a damping function whose role is to scale the force field such as to minimize the contributions from interactions within typical bonding distances. In practice, the terms in the equation for corresponding to interactions over distances longer than a certain suitably chosen cutoff radius (VDW_RADIUS, see below) contribute only negligibly to and can be ignored. Parameters and are computed using the following combination rules:
and
The values for and are tabulated for each element and are insensitive to the particular chemical situation (for instance, for carbon in methane takes exactly the same value as that for C in benzene within this approximation). In the DFT-D2 method, a Fermi-type damping function is used:
whereby the global scaling parameter has been optimized for several different DFT functionals such as PBE (), BLYP () or B3LYP (). The parameter is usually fixed at 1.00. The DFT-D2 method can be activated by setting IVDW=1|10 or by specifying LVDW=.TRUE. (this parameter is obsolete as of VASP.5.3.3). Optionally, the damping function and the vdW parameters can be controlled using the following flags (the given values are the default ones):
- VDW_RADIUS=50.0 : cutoff radius (in ) for pair interactions
- VDW_S6=0.75 : global scaling factor (available in VASP.5.3.4 and later)
- VDW_SR=1.00 : scaling factor (available in VASP.5.3.4 and later)
- VDW_SCALING=0.75 : the same as VDW_S6 (obsolete as of VASP.5.3.4)
- VDW_D=20.0 : damping parameter
- VDW_C6=[real array] : parameters () for each species defined in the POSCAR file
- VDW_R0=[real array] : parameters () for each species defined in the POSCAR file
- LVDW_EWALD=.FALSE. : the lattice summation in expression is computed by means of Ewald's summation (.TRUE. ) or via a real space summation over all atomic pairs within cutoff radius VDW_RADIUS (.FALSE.). (available in VASP.5.3.4 and later)
The performance of PBE-D2 method in optimization of various crystalline systems has been tested systematically in reference [2].
Important: It is recommended to use the more advanced and more accurate method DFT-D3.[3] |
Mind:
|
Related tags and articles
VDW_RADIUS, VDW_S6, VDW_SR, VDW_SCALING, VDW_D, VDW_C6, VDW_R0, LVDW_EWALD, IVDW, DFT-ulg, DFT-D3, DFT-D4