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Revision as of 10:30, 15 April 2012
Manual 03 for MD++
Equilibrium Lattice Constant and Bulk Modulus
Keonwook Kang and Wei Cai
Contents |
Reading a Log File
In the example scripts of Manual 02, the command setnolog was activated and the simulation results were printed out to the standard output, which is usually your terminal screen. If you want to keep the record of this information, you comment out the setnolog command by adding # before it. This will create a log file A.log in the directory specified by dirname. For example, if you run mo.script in Manual 02 with setnolog commented out, then you will find a A.log file in the runs/mo-example directory. To read this file, type
$ more runs/mo-example/A.log
In the log file, the line starting with ASSIGN shows that a variable is assigned to the values as specified in the script file. The line with EXEC shows the execution of certain command. After the eval command is executed, properties such as number of atoms (NP), potential energy (EPOT), kinetic energy (KATOM), pressure (PRESSURE) and stress (Stress) are also printed. Sometimes, the log file may be zipped as A.log.gz, in which case you can use
$ gzip -cd runs/mo-example/A.log.gz | more
to see the content. To search for a specific property (e.g. EPOT) in the log file, you may use
$ grep EPOT runs/mo-example/A.log
or
$ gzip -cd runs/mo-example/A.log.gz | grep EPOT
depending on whether the log file is zipped or not. In case you want to “grep” several lines before and after your keyword (e.g. Stress), you can use
$ grep -3 Stress runs/mo-example/A.log
This will show three lines above and below any line containing the keyword “Stress”.
Obviously, this way of extracting the values of MD++ variables is very tedious. There is a better way to do this, which is to use the Tcl scripting language, as described in Manual 08 (will be available soon). The Tcl script for MD++ calculations described in this section is attaced at the end of this manual.
Equilibrium Lattice Constant and Cohesive Energy
Under ambient condition silicon takes the diamond-cubic (DC) structure. But in a computer simulation, we can create Si crystals with different hypothet- ical structures, such as face-centered-cubic (FCC), body-centered-cubic (BCC), or simple-cubic (SC). A good potential model should be able to tell us that the DC structure is the one with the lowest energy, hence it is the most favorable structure for silicon. In this section, we will perform such calculations using MD++.
Let us define the lattice energy Φ and the number density ρ as
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where Epot is the potential energy of the crystal, N is total number of atoms in the simulation cell (corresponding to variable NP in MD++) and V is the volume of the simulation cell. Run MD++ with following command line to use the Stillinger-Weber (SW) potential model<ref name="SW">F. H. Stillinger and T. A. Weber, Phys. Rev. B 31, 5262 (1985).</ref><ref name="BH">H. Balamane, T. Halicioglu, and W. A. Tiler, Phys. Rev. B 46, 2250 (1992)</ref>.
$ bin/sw_gpp scripts/ME346/si_polytype.script
Here is the content of the si_polytype.script.
# -*-shell-script-*- #setnolog setoverwrite dirname = runs/si_polytype #------------------------------------------------------------ #Create Perfect Lattice Configuration # crystalstructure = diamond-cubic latticeconst = 5.4309529817532409 #(A) for Si latticesize = [ 1 0 0 3 0 1 0 3 0 0 1 3] makecrystal eval latticeconst = 4.850 makecrystal eval latticeconst = 4.950 makecrystal eval latticeconst = 5.050 makecrystal eval : (many lines omitted here for brevity) : latticeconst = 5.900 makecrystal eval latticeconst = 6.000 makecrystal eval latticeconst = 6.100 makecrystal eval crystalstructure = face-centered-cubic latticeconst = 4.105 makecrystal eval latticeconst = 4.110 makecrystal eval : : latticeconst = 4.205 makecrystal eval latticeconst = 4.215 makecrystal eval crystalstructure = body-centered-cubic latticeconst = 3.210 makecrystal eval latticeconst = 3.220 makecrystal eval : : latticeconst = 3.320 makecrystal eval latticeconst = 3.340 makecrystal eval crystalstructure = simple-cubic latticeconst = 2.550 makecrystal eval latticeconst = 2.600 makecrystal eval : : latticeconst = 2.640 makecrystal eval latticeconst = 2.650 makecrystal eval quit
From the log file, you can find number of atoms NP for the 3 X 3 X 3 DC cell to be 216. This number can also be obtained by calculating , since there are eight atoms in the DC unit cell. For other crystal structures, the number of atoms in the 3X3X3 cell is given in the following table.
Crystal Structure | No. of atoms in the unit cell | Total No. of atoms |
SC | 1 | 27 |
BCC | 2 | 54 |
FCC | 4 | 108 |
DC | 8 | 216 |
The potential energy at each different lattice constant can also be read from the log file by typing
$ grep EPOT runs/si_polytype/A.log
The volume of a simulation cell V can be obtained from the determinant of the matrix .<ref>The matrix defines size and shape of the simulation cell. where 's are three periodicity vectors. In MD++, the matrix becomes a diagonal matrix when the supercell is a rectangular box (after reorienting the coordinate system). </ref> When is a diagonal matrix (the same is true for an upper triangular matrix),
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the volume is the product of the entries in the main diagonal of . The unit of length in MD++ is Å and the unit of volume is Å3 . From these, we can calculate the lattice energy Φ (in eV) of silicon as a function of the number density ρ (in 1/Å3), for different crystal structures, as shown in Fig.1. The structure with the lowest energy is DC. The equilibrium lattice constant a0 corresponds to the number density that gives the minimum of the Φ(ρ) curve. The minimum of Φ is also called the cohesive energy Ecoh . For DC silicon, a0 = 5.431 Å and Ecoh = −4.63 eV.
Bulk Modulus
The curvature of the Φ(ρ) curve near the minimum also tells us the bulk modulus of the crystal. The bulk modulus B is defined as<ref>This is because and .</ref>
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where V0 is the equilibrium atomic volume (corresponding to the energy minimum). To compute the second derivative, plot Φ as a function of V = 1 / ρ and fit the Φ(V) curve by a quadratic function, i.e. Φ = c0 + c1V + c2V2, as shown in Fig.3. This can be done by the Matlab command polyfit and the result is c2 = 0.016879 (in unit of eV/Å6 ). Then, with V0 = 20.023 (Å3), the bulk modulus becomes
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This result matches with an earlier report in the literature<ref name="BH"/>. In the elasticity theory<ref>J. P. Hirth and J. Lothe, Theory of Dislocations, (Wiley, New York, 1982)</ref>, the bulk modulus B is related to the other elastic constants through
for isotropic material | |
for cubic material |
where λ and μ are Lamé's constants and C11 and C12 are cubic elastic constants. From this relation, the bulk modulus would be 98.4 GPa if we calculate it from the experimental value of C11 = 165.7(GPa) and C12 = 63.9(GPa) for silicon. The discrepancy between the simulation and experimental results in the bulk modulus is partly because the simulation results corresponds to the ideal case of T = 0 K, while the experimental result is obtained at room temperature T = 300 K. The elastic constants generally decreases with increasing temperature. The discrepancy may also come from the fact that the potential model has empirical nature. Different parameterization of the potential model generally leads to different predictions of the elastic constants.
Tcl version of MD++ script
For anyone that wants to reproduce my data, I uploaded the Tcl version of MD++ script si_polytype.tcl and the matlab script for the post-process of the simulation data.
si_polytype.tcl
# -*-shell-script-*- #******************************************* # Definition of procedures #******************************************* proc initmd { } { MD++ { #setnolog setoverwrite dirname = runs/si_polytype zipfiles = 1 # zip output files NIC = 200 NNM = 200 }} proc makecrystal { } { #-------------------------------------------- # Create Perfect Lattice Configuration MD++ element0 = Si MD++ latticesize = \[ 1 0 0 4 0 1 0 4 0 0 1 4 \] MD++ makecrystal } proc readnwrite { a fileID } { #-------------------------------------------- # read and write properties for {set i -50} {$i <= 50} {incr i} { set latt [expr $a + $i/10000.0 ] MD++ latticeconst = $latt makecrystal MD++ eval set EPOT [MD++_Get EPOT] set N [MD++_Get NP] set VOL [MD++_Get OMEGA] set ELAT [expr $EPOT / $N] set rho [expr $N / double($VOL)] set AtomVol [expr double($VOL) / $N] puts $fileID "[format %18.12e $latt]\t \ [format %18.12e $rho] \t \ [format %18.12e $AtomVol]\t \ [format %18.12e $EPOT]\t \ [format %18.12e $ELAT]" }} #******************************************* # Main program starts here #******************************************* initmd MD++ crystalstructure = diamond-cubic set a 5.4309 set fileID [open "EvsVol_DC.dat" w] readnwrite $a $fileID close $fileID MD++ crystalstructure = face-centered-cubic set a 4.1465 set fileID [open "EvsVol_FCC.dat" w] readnwrite $a $fileID close $fileID MD++ crystalstructure = body-centered-cubic set a 3.245 set fileID [open "EvsVol_BCC.dat" w] readnwrite $a $fileID close $fileID MD++ crystalstructure = simple-cubic set a 2.6120 set fileID [open "EvsVol_SC.dat" w] readnwrite $a $fileID close $fileID MD++ quit
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Matlab script to plot the lattice energy of Si % in different structures (DC, FCC, BCC and SC) %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% clf DC.data = load('EvsVol_DC.dat'); DC.latt = DC.data(:,1); DC.rho = DC.data(:,2); DC.atomvol = DC.data(:,3); DC.EPOT = DC.data(:,4); DC.ELAT = DC.data(:,5); FCC.data = load('EvsVol_FCC.dat'); FCC.latt = FCC.data(:,1); FCC.rho = FCC.data(:,2); FCC.atomvol = FCC.data(:,3); FCC.EPOT = FCC.data(:,4); FCC.ELAT = FCC.data(:,5); BCC.data = load('EvsVol_BCC.dat'); BCC.latt = BCC.data(:,1); BCC.rho = BCC.data(:,2); BCC.atomvol = BCC.data(:,3); BCC.EPOT = BCC.data(:,4); BCC.ELAT = BCC.data(:,5); SC.data = load('EvsVol_SC.dat'); SC.latt = SC.data(:,1); SC.rho = SC.data(:,2); SC.atomvol = SC.data(:,3); SC.EPOT = SC.data(:,4); SC.ELAT = SC.data(:,5); %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % plot the lattice energy vs number density % with inset figure h1 = figure(1); set(gca,'fontsize',14) plot(DC.rho, DC.ELAT, '.-',FCC.rho, FCC.ELAT, '.-', ... BCC.rho, BCC.ELAT, '.-',SC.rho, SC.ELAT, '.-') xlabel('Number Density, \rho=N/V (1/Angstrom^3)','fontsize',16), ylabel('Binding Energy per atom (eV)','fontsize',16) legend('DC','FCC','BCC','SC',2) h2 = get(h1,'CurrentAxes') h3 = axes('pos',[.5 .2 .35 .35]); hold on; plot(DC.rho, DC.ELAT, '.-') yticklong = get(h3,'YTick'); set(h3,'xlim',[0.0498 0.0501],'YTickLabel',yticklong,'box','on'); hold off %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % plot the lattice energy vs lattice constant % and find the equilibrium lattice constant, a_0 [P, S] = polyfit(DC.latt,DC.ELAT,2); latt_X = linspace(5.4305,5.4315); ELAT_Y = polyval(P,latt_X); figure(2) set(gca,'fontsize',14) plot(DC.latt, DC.ELAT, '.-',latt_X,ELAT_Y,'.-r') xlabel('Lattice Constant, \it a \rm (Angstrom)','fontsize',16), ylabel('Binding Energy per atom (eV)','fontsize',16) yticklong = get(gca,'YTick'); set(gca,'YTickLabel',yticklong,'Xlim',[5.426 5.436]); legend('data','fitting curve') %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % plot the lattice energy vs atomic volume % and find the bulk modulus, B [P2, S2] = polyfit(DC.atomvol,DC.ELAT,2); vol_X = linspace(20.01,20.04); ELAT_Y2 = polyval(P2,vol_X); figure(3) set(gca,'fontsize',14) plot(DC.atomvol, DC.ELAT, '.-',vol_X,ELAT_Y2,'.-r') xlabel('Atomic Volume, \it V \rm (Angstrom^3)','fontsize',16), ylabel('Binding Energy per atom (eV)','fontsize',16) yticklong = get(gca,'YTick'); set(gca,'YTickLabel',yticklong); legend('data','fitting curve')