19 June 2012

195. Frequency calcs in NWChem

It's no secret that I'm a computational 'noob'. As such as I'm learning both by reading and by doing.

The doing part consists of checking 1) what the time penalty for different methods is and 2) what the accuracy/differences between different methods are.

Again, these are short calculations for simple molecules. Longer calculations with more exciting features (unpaired electrons, closely spaced MOs, highly negative charges etc.) may well behave completely different.

Today's focus is vibrational calcs.

Test Molecule: CHClF(OH) (chloro-fluoro-methanol)
  1 Title "Freq_test"
  2 
  3 Start  Freq_test
  4 
  5 echo
  6 
  7 charge 0
  8 
  9 geometry noautosym units angstrom
 10  C     0.0416942     -0.501783     0.399137
 11  H     0.0442651     -0.499048     1.48122
 12  O     1.21393     -1.00985     -0.0746688
 13  H     1.25125     -0.957351     -1.06923
 14  F     -1.08480     -1.08768     -0.134571
 15  Cl     -0.120345     1.41214     -0.0717951
 16 end
 17 
 18 ecce_print ecce.out
 19 
 20 basis "ao basis" cartesian print
 21   H library "3-21G"
 22   F library "3-21G"
 23   Cl library "3-21G"
 24   O library "3-21G"
 25   C library "3-21G"
 26 END
 27 
 28 dft
 29   mult 1
 30   odft
 31   mulliken
 32 end
 33 
 34 task dft energy
 35 task dft freq

All geometries were optimised in the gas phase using 3-21G.

0. Some useful statements:
hessian      print "hess_follow"
                 profile
end
1. Basis set (geometry optimised in 3-21g)
(time/enthalpy/entropy/scfe)
3-21G:              81s    24.984 kcal/mol    69.235 cal/mol-K   -671.17956992206 Hartree
6-31G:            105s    21.885 kcal/mol    68.793 cal/mol-K   -674.478768966106
6-31++G**:    399s   21.734 kcal/mol     68.818 cal/mol-K   -674.573524091623
cc-pVDZ:        325s    21.682 kcal/mol    68.819 cal/mol-K   -674.594059146606
aug-cc-pVDZ:  901s   21.605 kcal/mol    68.840 cal/mol-K   -674.623145113155

LANL2DZ(C)/6-+G* 262s  24.923 kcal/mol 68.981 cal/mol-K  -674.539040349134
UHF/aug-cc-pVDZ   373 s 26.196  kcal/mol 68.228 cal/mol-K -672.85402652170

Cation:
3-21G:               ---     21.164 kcal/mol     74.407 cal/mol-K    -670.763278724519 Hartree
6-31G:              142s   21.153 kcal/mol     74.645 cal/mol-K    -674.089132280731
6-31++G**:      637s   21.192 kcal/mol    73.768 cal/mol-K    -674.178146586266
cc-pVDZ:          399s   21.153 kcal/mol    73.736 cal/mol-K    -674.210312017948
aug-cc-pVDZ:   1776s 21.089 kcal/mol     73.774 cal/mol-K   -674.228204222891

LANL2DZ(C)/6-+G* 454s 24.795 kcal/mol  74.293 cal/mol-K -674.140922359750
UHF/aug-cc-pVDZ  741s 26.002 kcal/mol  72.462 cal/mol-K  -672.518095855130

2. Thermochemistry (ΔG of oxidation; gas phase)
3-21G:            -5.3620 kcal/mol +  261.22 kcal/mol =  6.814 V*
6-31G:            -2.4768 kcal/mol +  244.50 kcal/mol =  6.214 
6-31++G**:    -2.0178 kcal/mol+  248.10 kcal/mol =  6.390 
cc-pVDZ:        -1.9950 kcal/mol + 240.80 kcal/mol =  6.075 
aug-cc-pVDZ: -1.9871 kcal/mol + 247.83 kcal/mol =  6.380

LANL2DZ(C)/6-+G* -1.7118 kcal/mol + 249.82 kcal/mol 6.478
UHF/aug-cc-pVDZ -1.4564 kcal/mol +210.80 kcal/mol = 4.797

* vs SHE=4.281 eV

3. Solvation (cosmo/water/scfe)
neutral
3-21g:                66s    22.097 kcal/mol    68.875 cal/mol-K   -671.1936338426 Hartree
6-31g:                82s    22.277 kcal/mol    68.609 cal/mol-K   -674.4934780299
6-31++g**:       277s   21.493 kcal/mol    69.353 cal/mol-K  -674.586704959695
cc-pVDZ:          266s   21.869 kcal/mol    68.808 cal/mol-K  -674.605608009070
aug-cc-pVDZ:    712s  22.116 kcal/mol    69.596 cal/mol-K   -674.635237990779

LANL2DZ(C)/6-31+G* 180s  25.022 kcal/mol   69.073 cal/mol-K -674.552417717602
UHF/aug-cc-pVDZ 412s  24.083 kcal/mol 70.519 cal/mol-K  -672.868085966222

cation (solvation energy)**

3-21G:               --- /26s        21.164 kcal/mol     74.407 cal/mol-K     -670.881469242560 Hartree
6-31G:              142s/51s      21.153 kcal/mol     74.645 cal/mol-K     -674.175491218588
6-31++G**:      637s/111s   21.192 kcal/mol    73.768 cal/mol-K      -674.267298880087
cc-pVDZ:          399s/129s   21.153 kcal/mol    73.736 cal/mol-K      -674.294609415029
aug-cc-pVDZ:   1776s/311s 21.089 kcal/mol     73.774 cal/mol-K     -674.316552324118

LANL2DZ(C)/6-31+G* 454s 24.795 kcal/mol  74.293 cal/mol-K -674.232656980139
UHF/aug-cc-pVDZ   741s 26.002 kcal/mol  72.462 cal/mol-K -672.451040948823
** UHF can't be used with COSMO according to nwchem. Instead we use the cation thermo calcs in the gas phase and use the scfe from a cosmo calc.

Thermochemistry*** (using gas phase freq for both cation and neutral species with scfe w/ cosmo given in parentheses):

3-21G:            -2.5824+195.88=  4.101 V (3.981 V)
6-31G:            -2.9236+199.54=  4.245 V (4.265 V)
6-31++G**:   -1.6173+200.43=  4.341 V (4.324 V)
cc-pVDZ:       -2.1853+195.15=  4.087 V (4.095 V)
aug-cc-pVDZ: -2.2727+199.98= 4.293 V (4.305 V)

LANL2DZ(C)/6-31+G*  -0.41322+200.65= 4.402
UHF/aug-cc-pVDZ 1.3397+261.7 (!)= 7.126
* vs SHE=4.281 eV

*** using freq calc of neutral species with cosmo, vs freq calc of cation in gas phase and energy w/ cosmo

4. Spectra
We'll use octave for this. First, using cat and gawk, I put the x/y coordinates in a file.

gauss= @(x,f,i,sigma)  i.*1./(sigma.*sqrt(2*pi)).*exp(-0.5.*((x-f)./sigma).**2)
subplot(3,2,1); axis([0 4000 0 2])
spc=load('321g.spc');sf=spc(:,1); si=spc(:,2);x=linspace(0,4000,800);spec=cumsum(gauss(x,sf,si,75)); 
title("321g"); plot(x,spec(18,:))
subplot(3,2,2)
spc=load('ccpvdz.spc');sf=spc(:,1); si=spc(:,2);x=linspace(0,4000,800);spec=cumsum(gauss(x,sf,si,75));
title("ccPVDZ");plot(x,spec(18,:))
subplot(3,2,3)
spc=load('631g.spc');sf=spc(:,1); si=spc(:,2);x=linspace(0,4000,800);spec=cumsum(gauss(x,sf,si,75));
title("631g"); plot(x,spec(18,:))
subplot(3,2,4)
spc=load('augccpvdz.spc');sf=spc(:,1); si=spc(:,2);x=linspace(0,4000,800);spec=cumsum(gauss(x,sf,si,75));
title("aug-ccPVDZ");plot(x,spec(18,:))
subplot(3,2,5)
spc=load('631gppdd.spc');sf=spc(:,1); si=spc(:,2);x=linspace(0,4000,800);spec=cumsum(gauss(x,sf,si,75));
title("631++g**"); plot(x,spec(18,:))

From top to bottom: Left: 3-21G, 6-31G, 6-31++G**. Right: cc-pVDZ, aug-cc-pVDZ
5. Conclusions
It may seem weird that as a test case I picked a species I don't have any reference potential for. However, the goal here was to understand how the basis set affects the results, without being distracted by such things as Real Life.

The observed spectra can be divided into two group: 3-21G/6-31G vs 6-31++G**/cc-pVDZ/aug-cc-pVDZ. Polarization (and diffuse functions) seem to play a large role.

In terms of thermochemistry, not surprisingly aug-cc-pVDZ and 6-31++G** give very similar results since they both implement pol/diff functions. The computational cost is, however, significantly higher for aug-cc-pVDZ than 6-31++G**, at least in nwchem.

There is also little difference between doing freq calculations in gas phase vs using cosmo when it comes to the calculated redox potential for the more extensive basis sets.

3-21G gives very varying results, with it giving the highest potential in the gas phase but the second lowest potential with cosmo. cc-pVDZ consistently gives the lowest potential.

UHF/ROHF/HF are fast, but wildly inaccurate. LANL2DZ/6-31+G* looks ok, results-wise, but the thermodynamic corrections are actually much smaller in conjunction with COSMO than the other methods, which is suspicious.

If given the time I may post a more detailed analysis of polarisation vs diffuse functions later.

17 June 2012

194. Wine 1.4.1 and Wine 1.5.6 on Debian Wheezy

UPDATE 16 May 2013: See here for Wine 1.5.30: http://verahill.blogspot.com.au/2013/05/416-wine-1530-in-chroot.html

There's great appetite for anything wine-related in Debian, as I can see from visitor numbers, so  here's how to build  Wine 1.4.1 and Wine 1.5.6 in Debian Testing/Wheezy. Enough talking -- let's get compilin'!

The builds take a little while, so be warned. Not all features are enabled in this particular build either -- see the configure output.

If you're interested in the missing development files seen below, this post might help: http://verahill.blogspot.com.au/2012/03/cross-compiling-eg-32-bit-binaries-on.html. Instinctively, I am suspicious as to whether that would work. I haven't explored it though, and my chief motivation is to make build instructions which anyone can easily follow and reproduce.

UPDATE (10th Jan 2013): See here for Wine 1.5.21 using the multiarch approach: http://verahill.blogspot.com.au/2013/01/308-compiling-wine-1521-on-debian.html


For both
sudo apt-get install bison flex gcc libc6-dev libfontconfig-dev libfreetype6-dev libglu-dev libgsm1-dev libice-dev libjpeg-dev libldap-dev libmpg123-dev libncurses5-dev libopenal-dev libpng-dev libsm-dev libssl-dev libusb-dev libx11-dev libxcomposite-dev libxcursor-dev libxext-dev libxi-dev libxinerama-dev libxml2-dev libxrandr-dev libxrender-dev libxslt-dev libxt-dev libxxf86vm-dev make libcapi20-dev liblcms-dev libsane-dev libhal-dev libdbus-1-dev valgrind prelink libcups2-dev opencl-dev lib32opencl1 oss4-dev gettext lib32v4l-dev lib32ncurses5-dev lib32asound2-dev lib32z-dev ia32-libs-dev


Version 1.4.1
wget http://prdownloads.sourceforge.net/wine/wine-1.4.1.tar.bz2

tar xvf wine-1.4.1.tar.bz2
cd wine-1.4.1/
./configure
configure: OpenCL 32-bit development files not found, OpenCL won't be supported.
configure: gstreamer-0.10 base plugins 32-bit development files not found, gstreamer support disabled
configure: libgsm 32-bit development files not found, gsm 06.10 codec won't be supported.
configure: libtiff 32-bit development files not found, TIFF won't be supported.
configure: WARNING: libjpeg 32-bit development files not found, JPEG won't be supported.
configure: Finished.  Do 'make' to compile Wine.
make
sudo checkinstall --install=yes

Note: To just make a .deb package, do ---install=no.

Version 1.5.6
wget http://prdownloads.sourceforge.net/wine/wine-1.5.6.tar.bz2
tar xvf wine-1.5.6.tar.bz2
cd wine-1.5.6/
./configure

configure: OpenCL 32-bit development files not found, OpenCL won't be supported.
configure: libsane 32-bit development files not found, scanners won't be supported.
configure: gstreamer-0.10 base plugins 32-bit development files not found, gstreamer support disabled
configure: libgsm 32-bit development files not found, gsm 06.10 codec won't be supported.
configure: libtiff 32-bit development files not found, TIFF won't be supported.
configure: WARNING: libjpeg 32-bit development files not found, JPEG won't be supported.
configure: Finished.  Do 'make' to compile Wine.
make
sudo checkinstall --install=yes

Note: To just make a .deb package, do ---install=no.

15 June 2012

193. Notes on UV/VIS - TD DFT in nwchem

I've been interested in looking at using NWChem to predict UV/VIS spectra. This post doesn't show how to do it but is rather just a look at what affects the positions of absorbances.
(although it more or less just involves
tddft
       cis
       nroots 24
end
task tddft energy)
I chose benzene and water as test cases. 

Here's water:
water

Reference spectrum in gas phase: http://www.lsbu.ac.uk/water/vibrat.html (166.5 nm) which tallies very well with 3-21g and 6-31g, but not at all with 6-31++g** or 3-21++g*.

Here's benzene:

Reference spectrum: http://www3.wooster.edu/chemistry/is/brubaker/uv/uv_spectrum.html
The reference spectrum, while a bit diffuse, shows the main absorbance at ca 178 nm. Presumably that's in benzene, not water.

More basis sets:


(cat Benzene_631g/Outputs/nwch.nwout |egrep "Root|sci"|gawk '{print $4,$6}'>bz631g.dat)