Becke and Johnson have proposed an exchange dipole model (XDM) of
dispersion.
78
J. Chem. Phys.
(2005),
122,
pp. 154104.
Link
,
584
J. Chem. Phys.
(2005),
123,
pp. 024101.
Link
The attractive dispersion energy
arises in this model via the interaction between the instantaneous dipole
moment of the exchange hole in one molecule, and the induced dipole moment in
another. This is a conceptually simple yet powerful approach that has been
shown to yield very accurate dispersion coefficients without fitting
parameters. This allows the calculation of both intermolecular and
intramolecular dispersion interactions within a single DFT framework. The
implementation and validation of this method in the Q-Chem code is described
in Ref.
639
Phys. Rev. A
(2009),
79,
pp. 042510.
Link
.
The dipole moment of the exchange hole function is given at point by
(5.38) |
where . This depends on a model of the exchange hole, and
the implementation in Q-Chem uses the Becke-Roussel (BR)
model.
80
Phys. Rev. A
(1989),
39,
pp. 3761.
Link
In most implementations the BR model, is
not available in analytic form and its value must be numerically at each grid
point. Q-Chem developed for the first time an analytical expression for this
function,
639
Phys. Rev. A
(2009),
79,
pp. 042510.
Link
based on non-linear interpolation and spline
techniques, which greatly improves efficiency as well as the numerical
stability.
Two different damping functions have been used with XDM. One of them relies only the intermolecular coefficient, and its implementation in Q-Chem is denoted as “XDM6”. In this version the dispersion energy is
(5.39) |
where is a universal parameter, and is the sum of the absolute values of the correlation energies of the free atoms and . The dispersion coefficients is computed according to
(5.40) |
where is the square of the exchange-hole dipole moment of atom , whose effective polarizability (in the molecule) is .
The XDM6 scheme can be further generalized to include higher-order dispersion coefficients, which leads to the “XDM10” model in Q-Chem:
(5.41) |
The higher-order dispersion coefficients are computed using higher-order
multipole moments of the exchange hole.
585
J. Chem. Phys.
(2006),
124,
pp. 174104.
Link
The quantity
is the sum of the effective van der Waals radii of
atoms and ,
(5.42) |
with a critical distance
(5.43) |
XDM10 contains two universal parameters, and , whose default
values of 0.83 and 1.35, respectively, were fit to reproduce intermolecular
interaction energies.
584
J. Chem. Phys.
(2005),
123,
pp. 024101.
Link
Becke later suggested several other XC
functional combinations with XDM, which employ different values of and
. The user is advised to consult the recent literature for
details.
79
Can. J. Chem.
(2010),
88,
pp. 1057.
Link
,
599
J. Chem. Theory Comput.
(2010),
6,
pp. 1081.
Link
As in DFT-D, the van der Waals energy is added as a post-SCF correction. Analytic gradients and Hessians are available for both XDM6 and XDM10. Additional job control and customization options are listed below.
DFTVDW_JOBNUMBER
DFTVDW_JOBNUMBER
Basic vdW job control
TYPE:
INTEGER
DEFAULT:
0
OPTIONS:
0
Do not apply the XDM scheme.
1
Add vdW as energy/gradient correction to SCF.
2
Add vDW as a DFT functional and do full SCF (this option only works with XDM6).
RECOMMENDATION:
None
DFTVDW_METHOD
DFTVDW_METHOD
Choose the damping function used in XDM
TYPE:
INTEGER
DEFAULT:
1
OPTIONS:
1
Use Becke’s damping function including term only.
2
Use Becke’s damping function with higher-order ( and ) terms.
RECOMMENDATION:
None
DFTVDW_MOL1NATOMS
DFTVDW_MOL1NATOMS
The number of atoms in the first monomer in dimer calculation
TYPE:
INTEGER
DEFAULT:
0
OPTIONS:
0–
RECOMMENDATION:
None
DFTVDW_KAI
DFTVDW_KAI
Damping factor for -only damping function
TYPE:
INTEGER
DEFAULT:
800
OPTIONS:
10–1000
RECOMMENDATION:
None
DFTVDW_ALPHA1
DFTVDW_ALPHA1
Parameter in XDM calculation with higher-order terms
TYPE:
INTEGER
DEFAULT:
83
OPTIONS:
10-1000
RECOMMENDATION:
None
DFTVDW_ALPHA2
DFTVDW_ALPHA2
Parameter in XDM calculation with higher-order terms.
TYPE:
INTEGER
DEFAULT:
155
OPTIONS:
10-1000
RECOMMENDATION:
None
DFTVDW_USE_ELE_DRV
DFTVDW_USE_ELE_DRV
Specify whether to add the gradient correction to the XDM energy.
only valid with Becke’s damping function
using the interpolated BR89 model.
TYPE:
LOGICAL
DEFAULT:
1
OPTIONS:
1
Use density correction when applicable.
0
Do not use this correction (for debugging purposes).
RECOMMENDATION:
None
DFTVDW_PRINT
DFTVDW_PRINT
Printing control for VDW code
TYPE:
INTEGER
DEFAULT:
1
OPTIONS:
0
No printing.
1
Minimum printing (default)
2
Debug printing
RECOMMENDATION:
None
$molecule 0 1 He 0.000000 0.00000 3.800000 N 0.000000 0.000000 0.546986 N 0.000000 0.000000 -0.546986 $end $rem JOBTYPE FREQ IDERIV 2 EXCHANGE B3LYP INCDFT 0 SCF_CONVERGENCE 8 BASIS 6-31G* !vdw parameters settings DFTVDW_JOBNUMBER 1 DFTVDW_METHOD 1 DFTVDW_PRINT 0 DFTVDW_KAI 800 DFTVDW_USE_ELE_DRV 0 $end
The original XDM implementation by Becke and Johnson used Hartree-Fock exchange
but XDM can be used in conjunction with GGA, meta-GGA, or hybrid functionals,
or with a specific meta-GGA exchange and correlation (the BR89 exchange and
BR94 correlation functionals, for example). Encouraging results have been
obtained using XDM with B3LYP.
639
Phys. Rev. A
(2009),
79,
pp. 042510.
Link
Becke has found more recently
that this model can be efficiently combined with the P86 exchange functional,
with the hyper-GGA functional B05. Using XDM together with PBE exchange plus
LYP correlation, or PBE exchange plus BR94 correlation, has been also found
fruitful. See Refs.
599
J. Chem. Theory Comput.
(2010),
6,
pp. 1081.
Link
and
920
J. Chem. Phys.
(2013),
138,
pp. 204109.
Link
for some recent choices in this regard.