CamCASP/Programming/7
CamCASP => Programming => Propagator
The new propagator module (in CamCASP 5.5-dev) can create the propagator in the LDAX approximation very efficiently. Construction scales as <math>O(N^4)</math>. Further, the kernel integrals are calculated with <math>O(N^3)</math> scaling (one power for grid points and two powers for auxiliary basis functions). So the new propagator can be calculated very efficiently. But the ALDAX approximation in the kernel results in significant errors in the polarizabilities and (probably dispersion energies).
As a temporary measure we could calculate the hybrid ADALX+CHF (not ALDA - I still don't have the VWN correlation functional programmed, but this is not a large error) by back transforming the kernel using the DF solution. So we go from a two-index object to a four-index object, then form the full propagator, and then transform back to a two-index density-fitted propagator. This is a round-about way, but should work and will still benefit from the efficiency gains in evaluating the kernel integrals.
Status
- Molecular grids need to be explicitly defined before calculating kernel integral internally. This is because the default grid is too fine. Use
BEGIN GRID MOLECULE <name> ANGULAR 100 RADIAL 60 END
- <math>N^6</math> algorithm: Kernel can be constructed internally using the ALDAX(DF)+CHF approximation. Energies and properties can use this route. Activate with
HESSIANS INTERNAL
in the propagator block. Accuracies high.
- <math>N^4</math> algorithm: Kernel can be constructed in the ALDAX approximation. As yet, no fraction of CHF can be added. Low accuracies when used with hybrid functionals like PBE0. Likely higher accuracies with GGAs. Have to test this. As yet only allowed for properties calculations. Needs commands
SET NEW-PROP KERNEL-EPS 0.00001 END BEGIN POLARIZABILITY MOLECULE <name> NEW-PROP ... END
Very fast and uses far less memory than the <math>N^6</math> algorithm. Can now be used in energy routines. Just add NEW-PROP to the commands.
- Basis sets: Any basis allowed. No restrictions on type of GTOs in auxiliary basis.
- ALDAX: The contribution from the correlation functional is still missing. This (I believe) is responsible for the residual (1-2%) errors in molecular properties and dispersion energies.
- Coded for closed-shell systems.
--alston 19:15, 27 April 2010 (BST)
To Do
- Use screening when calculating kernel integrals. Probably use the overlap matrix as a screen.
- Hybrid Hessians in new propagator module.
Concerns
Numerical Integrals
- Becke smoothing parameter: Surely the integration result should not depend on the choice of this parameter. But it does. I have not systematically explored this issue, but here are some energies for the water dimer:
Energies in kJ/mol elst ind2C disp2C exch exind2C exdisp2C becke100.out -28.499 -10.832 -9.971 24.756 5.624 1.670 becke10.out -28.499 -10.829 -9.964 24.756 5.622 1.669 becke3.out -28.499 -10.829 -9.962 24.756 5.622 1.668
The default parameter is 3. Increasing it makes the swicthover 'harder' - that is, more abrupt. But I certainly do not fully understand what this parameter does. Should dig into the matter.--alston 12:09, 3 May 2010 (BST)
The problem could arise from the cutoffs. The kernel integrals use a cutoff to evaluate <math>\rho^{-2/3}</math>. This is done only for densities larger than <math>\epsilon</math>; else this term is dropped. Changing the Becke parameter changes the weights (obviously). Now if my chosen value of <math>\epsilon</math> is too large, then the Becke parameter may have an effect on the results. I should experiment with smaller values of <math>\epsilon</math>. --alston 16:33, 3 May 2010 (BST)
The problem doesn't seem straightforward. Here are some observations:
- EFFICIENCY: The grid consists of atomic grids. Connected atoms share points. So the grid contains several instances of points. This is very wasteful. There must be some way of reducing the atom grids into one molecular grid. I must look into it.
- ACCURACY: We can achieve 4 decimal numerical accuracy for the dipole polarizability of water if we use very large grids (400 radial, 600 angular). For such grids, the Becke smoothing parameter doesn't change results (I used parameter values of 2, 4 and 10). But even with this large grids, the quadrupole polarizabilities differ in the second or third place as the smoothing parameter is varied.
- APPROXIMATIONS: Using extremely large grids is not practical. So we must compromise. For a given choice of KernelEps and grid size (60 radial and 100 angular) what Becke smoothing parameter is appropriate? Based on the dipole-dipole polarizabilities of water, it seems like a value around 4 is appropriate. This is the default. Larger values (~10) cause significant change to the polarizability anisotropy. Smaller values (~2) seem to result in slightly larger errors in the quadrupole polarizabilities, but these are not quite significant enough. So, I'd say a value of 2 to 4 should be OK. The default value is 3.
Water aTZ/aTZ PBE0/AC ALDAX Radial Angular Becke KernelEps alpha anisotropy ================================================== Reference values: 400 600 10 1.0e-8 8.2391 1.0236 400 600 2 1.0e-8 8.2390 1.0238 300 400 10 1.0e-8 8.2391 1.0236 300 400 2 1.0e-8 8.2390 1.0238 200 400 10 1.0e-8 8.2392 1.0238 200 400 2 1.0e-8 8.2391 1.0239 -------------------------------------------------- 60 100 10 1.0e-8 8.2409 1.0178 60 100 4 1.0e-8 8.2387 1.0235 60 100 2 1.0e-8 8.2386 1.0237 --------------------------------------------------
The reference values use very large grids and result in dipole-dipole polarizabiliites that are fairly insensitive to the Becke parameter. There is a larger variation for the smaller grid, with the agreement getting rather good for smaller values. --alston 18:55, 3 May 2010 (BST)
Kernel Notation
- AUX-ALDA : ALDA kernel constructed directly in auxiliary basis.
- AUX-ALDAX : ALDAX exchange-only LDA kernel constructed directly in auxiliary basis.
- DF-(ALDA+CHF) : Hybrid ALDA+CHF kernel constructed in main basis, and then reduced in size using density-fitting.
- DF-(ALDAX(DF)+CHF) : As above, but with exchange-only ALDAX kernel calculated from AUX-ALDAX and converted into an ov x ov object using the DF solution matrix.
Examples
Benzene
- Basis: Sadlej
- Old timings obtained using different processor (AMD), so using pyridine/sadlej timings (note: smaller basis set!):
- DALTON: Kernel integrals: 3.3 hours
- CamCASP: (properties) 2.5 hours
- New timings (AUX-ALDAX kernel):
- Kernel: 6.5 minutes
- CamCASP (only total polarizabilities): 12 minutes
Not quite a good comparison, but you get the idea. The new propagator is very very fast.
Accuracy is poor. ALDAX is just not good enough for <math>\pi</math>-conjugated systems. Here are the dipole-dipole polarizabilities:
DF-(ALDA+CHF) kernel:
43.247483 0.000000 0.000000 0.000000 80.710408 0.000000 0.000000 0.000000 80.713103 Isotropic polarizability: 68.22366473 Anisotropic polarizability: 37.46427266
AUX-ALDAX kernel:
Order: 1 by 1 39.035569 0.000000 0.000000 0.000000 70.478442 0.000000 0.000000 0.000000 70.487565 Isotropic polarizability: 60.00052553 Anisotropic polarizability: 31.44743535
That's a 12% error.
I've now made the new kernel integral routines accessible from the old densfit_prop.F90 module. This is a temporary work-around to allow us to use the hybrid Hessians. Here's what I get for benzene:
DF-(ALDAX(DF)+CHF) kernel:
42.787209 0.000000 0.000000 0.000000 80.353396 0.000000 0.000000 0.000000 79.887600 Isotropic polarizability: 67.67606832 Anisotropic polarizability: 37.33546875
The error is now 0.8%. There still is a difference for these reasons (I think):
- I have constructed the ov x ov kernel integrals using the expression <math>H = D K D^T</math> where <math>D</math> is the OV density-fitting solution matrix and <math>K</math> is the kernel calculated in the auxiliary basis.
- The kernel integral is calculated in the ALDAX approximation. I still do not have the contribution from the correlation functional.
- The auxiliary basis uses Spherical GTOs.
It's hard to say which is the dominant source of error. But the total error is quite small now, so perhaps we can live with this for now.
Timings: it's slower than the previous method (using AUX-ALDAX), but only by a minute.
Completed the Cartesian aux basis calculation: DF-(ALDAX(DF)+CHF) kernel:
42.614128 0.000000 0.000000 0.000000 79.929958 0.000000 0.000000 0.000000 79.930117 Isotropic polarizability: 67.49140129 Anisotropic polarizability: 37.31590957
Error here is 1.1%. More than the spherical aux case. This is strange. Well, anyway, the error is still small. So the residual error in the calculation must be from the DF or ALDAX approximations.
--alston 19:31, 26 April 2010 (BST)
- PBE noAC
- ALDAX kernel
44.072016 0.000000 0.000000 0.000000 83.389575 0.000000 0.000000 0.000000 83.385620 Isotropic polarizability: 70.28240379 Anisotropic polarizability: 39.31558132
PBE overestimates the polarizability. This is a failure of GGAs in general and has been shown to get worse as the HOMO-LUMO gap reduces. But for systems the size of benzene, PBE with the ALDAX kernel should be a very good approximation. The error in the polarizability is only 3% (overestimation). This would likely amount to a 6% error in the long-range dispersion. At short range overlap effects often compensate, though this cannot be relied upon.
Time: This calculation took 20 minutes (full properties) in CamCASP and 9 minutes in DALTON.
--alston 13:07, 30 April 2010 (BST)
Water
- Basis: aug-cc-pVTZ
- Aux: aux-aug-cc-pVTZ Cartesian GTOs
- XC-Func: PBE0
Here is the dipole-dipole polarizability using the DF-(ALDA+CHF), DF-(ALDAX(DF)+CHF) and AUX-ALDAX kernels.
DF-(ALDA+CHF):
9.391882 0.000000 0.000000 0.000000 10.034214 0.000000 0.000000 0.000000 8.750848 Isotropic polarizability: 9.39231483 Anisotropic polarizability: 1.11142748
DF-(ALDAX(DF)+CHF):
9.259201 -0.000000 0.000000 -0.000000 9.901715 0.000000 0.000000 0.000000 8.617225 Isotropic polarizability: 9.25938032 Anisotropic polarizability: 1.11240073
AUX-ALDAX:
8.227020 -0.000000 0.000000 -0.000000 8.808915 0.000000 0.000000 0.000000 7.683247 Isotropic polarizability: 8.23972716 Anisotropic polarizability: 0.97504333
Once again large (12.2%) errors with the AUX-ALDAX kernel but far better agreement (1.4%) with the DF-(ALDAX(DF)+CHF) kernel. --alston 19:00, 26 April 2010 (BST)
Helium dimer
- Basis: aTZ/MC+
- Geom: R = 5.6 a.u.
Here's a comparison of interaction energies from the original method (ALDA+CHF kernel using DALTON, Cartesian auxiliary basis) and the new method (DF-(ALDAX+CHF) kernel using CamCASP, spherical auxiliary basis):
Energy-units cm-1 elst exch disp2C ind2C exind2C exdisp2C Eint(2) Original DF-(ALDA+CHF) -1.27 8.88 -15.684454 -0.216497 0.179052 0.449355 -7.657907 New DF-(ALDAX(DF)+CHF) -1.22 8.88 -15.417550 -0.464630 0.383947 0.441358 -7.390518
There is a large change in the induction energies because of the use of spherical GTOs in the auxiliary basis - this energy is very sensitive to the accuracy of the density fitting. There is an error of 1.7% in the dispersion energy.
Water dimer
- Basis: Sadlej/DC+
- Geom: Global minimum in energy.
Energy-units kJ/mol elst ind2C disp2C exch exind2C exdisp2C E2int DF-(ALDA+CHF) PBE0/AC -28.941 -10.567 -9.728 23.740 5.507 1.649 -18.340 DF-(ALDAX(DF)+CHF) PBE0/AC -28.941 -10.467 -9.581 23.740 5.457 1.624 -18.169 DF-ALDAX PBE0/AC -28.941 -9.756 -8.872 23.740 5.097 1.504 -17.229 DF-ALDAX PBE/AC -28.499 -10.832 -9.962 24.756 5.624 1.668 -17.246 DF-ALDAX PBE -29.032 -13.262 -10.636 28.511 8.000 1.988 -14.430
Errors: PBE0/AC
- DF-(ALDAX(DF)+CHF)
- Dispersion: 1.5% in E2disp,pol
- E2int : 0.9%
- DF-ALDAX
- Dispersion: 10.3% in e2disp,pol
- E2int : 6%
The error made by the DF-(ALDAX(DF)+CHF) propagator are not large, but should be eliminated at some point soon! On the other hand, the errors made by the DF-ALDAX propagator are quite substantial.
As can be seen, the asymptotic correction is very important for water. The effect is mainly in the exchange energies.
XVI dimer
- From this year's Blind Test.
- Quite a large molecule: C6ON2H4 (Benzene ring with C=O next to C=N=N).
- Basis: Sadlej/MC+ : size=404 spherical GTOs
- Aux: aug-cc-pVTZ/DC+ : 2953 Cartesian GTOs
- Geometries: Angstrom, Degrees.
INDX Rx Ry Rz Alpha Nx Ny Nz 1 -3.962203 -0.306308 3.248817 0.000000 0.000000 0.000000 1.000000 2 -1.176349 6.896238 -0.246782 0.000000 0.000000 0.000000 1.000000
- Geometry 1:
elst ind2C disp2C exch exind2C exdisp2C Total Diff Timings (DAL,CamCASP) PBE0 AC ALDA+CHF -6.114 -10.220 -25.462 18.197 8.448 2.002 -13.149 36h 11h20m (Dalton direct, conv 10-7) PBE noAC ALDAX -6.563 -11.424 -25.981 20.223 9.529 2.092 -12.125 7.8% 11h45m 12h56m (Dalton direct, conv 10-7) PBE AC ALDAX -6.093 -10.207 -25.394 18.867 8.332 1.940 -12.554 4.5% 12h 11h45m (Dalton no direct, conv 10-6)
With PBE/noAC-ALDAX there is only a 0.5 kJ/mol difference in the dispersion energy. Most of the error arises from the electrostatic, induction and exchange energies - all, I'm sure, because of the lack of the asymptotic correction. There is a substantial decrease in the time taken per job when the ALDAX kernel is used. The lack of AC also contributes. DALTON takes a total of 18h to calculate the Kernel integrals. CamCASP takes 3h46m. This is the biggest time reduction. PBE/AC-ALDAX is probably the way to go. The large errors in the exchange energies that we see with PBE/noAC are largely corrected with the AC. The error in the interaction energy is now under 5%. This is acceptable. Also, without the .DIRECT option, DALTON seems quite fast and is able to implement the AC in almost the same time.
- Geometry 2:
elst ind2C disp2C exch exind2C exdisp2C Total Diff Timings (DAL,CamCASP) PBE0 AC ALDA+CHF -12.058 -4.139 -11.157 9.047 1.424 0.827 -16.056 31h48m 10h33m PBE noAC ALDAX -12.069 -4.862 -11.919 11.528 1.997 0.981 -14.342 10.7% 10h47m 12h48m
There is no screening used in the kernel integral routines in CamCASP so we see a very small reduction in time compared with Geometry 1. --alston 12:53, 3 May 2010 (BST)