Difference between revisions of "Code:gmxliquid"
(→analyze dynamic data) |
|||
Line 164: | Line 164: | ||
by watching the mean squared displacement of the molecules over time. Since |
by watching the mean squared displacement of the molecules over time. Since |
||
the distance traveled over a random walk with diffusion constant <math>D</math> |
the distance traveled over a random walk with diffusion constant <math>D</math> |
||
− | has a Gaussian distribution with variance <math>2D\Delta t<math>, where <math>\Delta t</math> |
+ | has a Gaussian distribution with variance <math>2D\Delta t</math>, where <math>\Delta t</math> |
is the elapsed time, the mean squared displacement vs time should be a straight line with |
is the elapsed time, the mean squared displacement vs time should be a straight line with |
||
slope <math>2D</math>. Of course, over short times, this picture is only approximate, |
slope <math>2D</math>. Of course, over short times, this picture is only approximate, |
Revision as of 11:33, 21 November 2014
In this tutorial, I'm assuming you already have the gromacs commands (grompp, mdrun, etc.) loaded. On circe at USF, this is done with:
module load apps/gromacs/4.5.5
You'll also need the starting files here.
Create an input system
First, we do some size calculations in the python prompt.
>>> # Compute number of EtOH molecules >>> # 8 nm^3 = 8e-21 cc >>> # 0.4 % By vol. >>> # rho_EtOH = 0.78924 g / cc >>> # FW = 46 g/mol >>> >>> 8e-21*0.4*0.78924/46.0*6.022e23 33
Next, we need to generate an 8 nm<math>^3</math> box with 33 EtOH molecules
genbox -box 2 2 2 -ci etoh.pdb -o box.pdb -nmol 33 nano topol.top # check for line "ETH 33" (no changes required)
If the topology file and forcefields are 'there', we can create a test simulation using just these molecules. We'll do this just to check that grompp works
grompp -c box.pdb -f equ.mdp -o equ.tpr
Next, the complete water+EtOH mixture can be made by filling the voids with water. We'll use TIP4P here.
genbox -cs tip4p -cp box.pdb -o sys.pdb
Since this last command added waters, you have to update the topology file, adding "SOL 133" (or your number of waters)
nano topol.top
run minimization
Molecular structures can be touchy, since contacting atoms causes large forces and 'blows up' a system. The risk of this can be reduced by minimizing the energy of initial starting systems.
First, we have to create a file describing how gromacs should do the minimization.
grompp -f min.mdp -c sys.pdb -o min
A lot of backup files (starting with '#') accumulate, and we remove them like so:
rm -f \#* mdout.mdp
Now we're ready to run minimization. Since the system is small, minimization is cheap and fast - so we do it on the head node. For larger systems, this command would be put in a job-script.
mdrun -s min -o min -g min -e min -c min
Now we're ready to take the minimized structure and run dynamics. This first round is called equilibration, since we intend to let the system settle into a thermal equilibrium state.
grompp -c min.gro -f equ.mdp -o equ.tpr
To run this one, we'll use the cluster by writing down the command in a script file. That script gets sent to the cluster. No changes to equ.sh should be required.
nano equ.sh sbatch equ.sh squeue -u `whoami`
As the job is running you can read through the log file.
less equ.log tail -f equ.log # enter Ctl-C to stop tailing
Note that the energy is output at every time-step. Why is the total energy changing with time? What about the total volume?
run dynamics
Running dynamics uses the same procedure as before, but now we need to worry about how much and which output to produce.
nano run.mdp # no changes required grompp -c equ.gro -f run.mdp -o run.tpr
Check and start equilibration job (no changes required).
nano run.sh sbatch run.sh squeue -u `whoami`
Read through run.log
less run.log tail -f run.log # enter Ctl-C to stop tailing
Notice that the total energy remains relatively constant now, but the individual energies are still very noisy. What does this say about the shape of the molecules?
analyze dynamic data
Let's first check what happened during equilibration. Since the volume was allowed to change, we should be able to plot it vs. time:
g_energy -f equ.edr -o equ.en.xvg # Select: Potential Kinetic-En. Total-Energy Volume
- At what time does the potential energy stabilize?
- What is the density?
- answer: (33*46 + 18*133)/Avogadro / 7.0333834916722191e-21 = 0.9236 g/mL
- These two quantities inform on the heat and volume change of mixing.
- Pure H2O (TIP4P): rho = 1.001, H ~ 11.6 kcal/mol, D = 3.9e-5 cm^2/s, eps = 52
- Pure H2O (expt): rho = 0.9971, H = 10.5 kcal/mol, D = 2.3e-5 cm^2/s, eps = 78.4
- (J. Chem. Phys. 123, 234505, 2005)
- Pure EtOH: rho = 0.7873, H = 10.0 kcal/mol, D = 1.0e-5 cm^2/s, eps(expt) = 23
- (J. Phys. Chem. B 1997, 101, 78-86, J. Phys. Chem. B, 2014, 118 (34), 10156-66)
Gnuplot can make this plot with
plot 'equ.en.xvg' u 1:2 w l, 'equ.en.xvg' u 1:5 axis x1y2 w l
The radial distribution function is a classical measure of the structuring of liquid water. The one we
calculate here shows the density of molecules within spherical shells around the central molecule.
g_rdf -rdf mol_com -ng 2 -f run.trr -o run.w-rdf.xvg # select Water as "reference group", select "Water", then "ETH" # re-run for ETH-ETH rdf g_rdf -rdf mol_com -ng 1 -f run.trr -o run.e-rdf.xvg
gnuplot can plot these together with:
plot 'run.w-rdf.xvg' u 1:2 w l, 'run.w-rdf.xvg' u 1:3 w l, 'run.e-rdf.xvg' u 1:2 w l
Notice how waters stack much more closely together than EtOH? How is this related to their liquid densities?
The dielectric of a liquid measures its ability to be polarized by an applied field. High dielectric materials make good capacitors.
g_dipoles -f run.trr -s run.tpr -c dipcorr.xvg -corr total -P 1
Dipole moment (Debye) --------------------- Average = 2.2234 Std. Dev. = 0.1095 Error = 0.0001 The following averages for the complete trajectory have been calculated: Total < M_x > = 7.79882 Debye Total < M_y > = -1.11977 Debye Total < M_z > = 9.49511 Debye Total < M_x^2 > = 882.516 Debye^2 Total < M_y^2 > = 1239.78 Debye^2 Total < M_z^2 > = 925.457 Debye^2 Total < |M|^2 > = 3047.75 Debye^2 Total |< M >|^2 = 152.233 Debye^2 < |M|^2 > - |< M >|^2 = 2895.52 Debye^2 Finite system Kirkwood g factor G_k = 3.52836 Infinite system Kirkwood g factor g_k = 2.37948 Epsilon = 43.1739
Water and EtOH are constantly undergoing random collisions in solution. The net effect of this is diffusion of the two molecules. Einstein showed that this can be tracked by watching the mean squared displacement of the molecules over time. Since the distance traveled over a random walk with diffusion constant <math>D</math> has a Gaussian distribution with variance <math>2D\Delta t</math>, where <math>\Delta t</math> is the elapsed time, the mean squared displacement vs time should be a straight line with slope <math>2D</math>. Of course, over short times, this picture is only approximate, but it usually holds over longer times.
g_msd -f run.trr -ngroup 2 -o run.msd.xvg
Fitting from 100 to 900 ps D[ Water] 1.4336 (+/- 0.0850) 1e-5 cm^2/s D[ ETH] 0.7312 (+/- 0.1279) 1e-5 cm^2/s
How do these compare with the literature values (above) for the pure liquids?
More detail on velocity correlation:
g_velacc -mol -f run.trr -o run.w-acf.xvg # Choose group 3 (Water) g_velacc -mol -f run.trr -o run.e-acf.xvg # Choose group 2 (ETH)
you can compare these to some of the above references.