TD calculations using ARIR

Thermodynamic calculations taking into account the internal rotations.
1. An automated procedure

MOLTRAN can perform the thermodynamic calculations taking into account the internal rotations contributions. It can be done or in a manual mode (using the commands in .tdi-file) either in completely automatic mode. The automatic mode is much more simple and useful. However, it will probably require some additional inspection of the results in order to verify some program decisions. Below, the results of the automatic mode calculations are reviewed using the SiF3-OH molecule as an example.

To obtain the presented results, use the above-mentioned sample file Moltran-Sample1.txt. Start MOLTRAN and open the file Moltran-Sample1.txt using the opening dialog or run the command from a command string:

moltran Moltran-Sample1.txt

Choose menu items: “Calculations”->“Thermodynamics”. In the window appeared check “Exit program after TD calculations” and click “OK”. The program will finish the work.

You can also use the way not requiring the interactive operations. Just run the command:

moltran Moltran-Sample1.txt /0 /arir

After the program is finished, the output file (Moltran-Samle1.log) contains the results of thermodynamic calculations taking into account the contribution of single internal rotation of OH group in SiF3OH.

The calculation is performed automatically, using the Automatic Recognition of Internal Rotations (ARIR) module implemented in MOLTRAN. The ARIR procedure uses an original algorithm. The method for TD accounting of internal rotations based on the theory developed by Pitzer, Gwinn, and Kilpatrick. (see J.Chem.Phys.1942,10).

Describing the output, we skip the beginning of file and the standard thermochemistry data and begin the discussion from the results of internal rotation treatment. The data of interest are started with a header:

*** Automatic Recognition of Internal Rotations ***

The ARIR procedure starts at this point. At first, it tries to identify “basis rotations”, i.e. rotations which do not change the connectivity matrix. In the current example, there is the only candidate corresponding to the rotation around atoms 1 and 5:

 *** Automatic Recognition of Internal Rotations ***

 Possible Internal Rotations :  1
 Int.Rot.  1   Axis:  1  5   NRot:  1   Atoms:  2  Group:  5  6

 Atom  XYZ   Internal Rotations
                1
 Si1    X    0.0000
        Y   -0.0001
        Z   -0.0112
 F2     X    0.0001
        Y    0.0000
        Z    0.0084
 F3     X    0.0237
        Y   -0.0074
        Z   -0.0053
 F4     X   -0.0238
        Y    0.0074
        Z   -0.0055
 O5     X    0.0001
        Y   -0.0003
        Z   -0.0405
 H6     X   -0.0021
        Y    0.0088
        Z    0.9984

Then, the normal modes are expanded in the basis rotations. Two of them (vibrational modes 7 and 9 with frequencies 113 and 276 cm-1) has expansion coefficients exceeding the predefined threshold:

  Vibrational modes expanded to internal rotations. (Int.Rot.threshold = 0.50)
  Mode  Frequency       Internal Rotation Coefficient
   No.     cm-1            1
    1      0.00         0.0000            
    2      0.00         0.0000            
    3      0.00         0.0000            
    4      0.00         0.0000            
    5      0.00         0.0000            
    6      0.00         0.0000            
    7    113.42        -0.9961

From these two modes MOLTRAN tries to choose only one mode (because there is only one basis rotation) which is most similar to a “pure internal rotation”. This procedure is internally ambiguous, even if we try to do that manually, because the “pure rotation” is a kind of idealization and we can not to represent any molecular moving by rotation only. The results of such assignment should be accepted with a caution. It is recommended to test the assignment using the MOLTRAN vibration animation procedure. Namely, check, whether the vibration is really similar to the vibration of one part of molecule relatively to another one.

 Vibrational modes which are most similar to internal rotations:
 (please check the program decision manually)
   No. Mode    Freq.         Internal Rotation Contributions (normalized)
                               1
    1    7    113.42        -1.0000

After the rotation mode is determined, MOLTRAN estimates the rotation barrier height. Using ARIR, the semiempirical procedure is utilized (PM3 by default), and the results are printed below:

 Estimation of internal rotation potential by PM3 method

 Relative potential energies in kJ/mol as a function of rotation angle
 No.  Angle   Internal rotation
      (deg)       1
  1    0.00    0.000000
  2   10.00    0.045191
  3   20.00    0.178237
  4   30.00    0.383180
  5   40.00    0.634619
  6   50.00    0.901563
  7   60.00    1.154014
  8   70.00    1.370036
  9   80.00    1.540072
 10   90.00    1.666867
 11  100.00    1.762051
 12  110.00    1.841670
 13  120.00    1.921974
 14  130.00    2.015356
 15  140.00    2.126254
 16  150.00    2.247998
 17  160.00    2.362756
 18  170.00    2.446492
 19  180.00    2.478258
 20  190.00    2.449524
 21  200.00    2.368188
 22  210.00    2.254823
 23  220.00    2.133464
 24  230.00    2.022228
 25  240.00    1.928187
 26  250.00    1.847272
 27  260.00    1.767353
 28  270.00    1.672318
 29  280.00    1.546128
 30  290.00    1.377003
 31  300.00    1.161891
 32  310.00    0.909959
 33  320.00    0.642805
 34  330.00    0.390276
 35  340.00    0.183442
 36  350.00    0.047936
 37  360.00    0.000000

Now, the internal rotation contribution is estimated. The molecular parameters used for this estimation is printed as follows:

 *** Contributions of internal rotations ***

 *** Internal rotation No.  1 (replacing the vibration mode  7) 

 Masses (amu) and moments of inertia (amu*bohr^2) of rotating groups:
 Group 1:  M1=  17.00274   I1=    2.45338
 Group 2:  M2=  84.97213   I2=  442.72681
 Reduced I=I1*I2/(I1+I2)     =    2.43986
 Pitzer's estimator I0       =    2.32452
 Pitzer's estimator I        =    2.32452
 Rotation axes:
 Point 1:  Atom  5  Coords:  3.039279  0.248852  0.004620
 Point 2:  Atom  1  Coords:  0.005754  0.014445  0.000036

The calculated rotation potential is expanded in a Fourier series in order to determine its folderness (rotation symmetry) to dermine the symmetry number needed in thermodynamic calculation. This determination is based on the calculation of maximum value of expansion coefficients in the Fourier series. Unfortunately, it is also very ambiguous procedure because the true potential is frequently masked by additional interactions. In this example, the procedure is failed to get correct symmetry of rotation potential: the obtained value is 1 instead of 3 (3-fold potential of rotation). This is a result of significant asymmetry of potential obtained at the PM3 level. It is interesting that the ab initio potentials are frequently more symmetric and the procedure gives the correct value of symmetry number. The symmetry number can be also be set manually using the TDI-file as described below.

 Rotation barrier is estimated from the Fourier-transformed rotational potential
 V = c0/2 + c1*Cos(x) + c2*Cos(2*x) + ... ,    0<=x<=Pi
 First coefficients are:
     n      C(n)
     0    25.83821
     1    -9.71418

The rotation barrier height is estimated on the basis of maximum value of potential curve. Because the obtained barrier height is lower than 1.4RT at the given temperature, the conclusion is made that this rotation is free:

 Rotation barrier height for n-fold potential V=V0/2*[1-Cos(n*x)] (n=1):
 V0 =     2.4783   kJ/mol
          0.5923 kcal/mol
          0.9997 RT   (T=  298.15K) => Free rotation (V0<1.4RT)

Now, the thermodynamic contribution is estimated. Free-rotation partition function used in Pitzer-Gwinn tables is printed out. Then the contribution of the current rotation mode is given in different approximations. The most comprehensive is the last column (obtained on the basis of Pitzer-Gwinn’s numeric tables for comprehensive estimator of inertia moments).

 Free-rotation function: 1/Qf =     1.946788E-01   Qf =     5.136666E+00
 Free-rotation (Pitzer): 1/Qf =     1.994503E-01   Qf =     5.013780E+00


 Thermodynamic functions for internal rotation  1 (vibration mode  7)

                  Harmonic   Free Rotator   Pitzer-Gwinn tables 
                 Ocsillator  I(*)    I(**)     I(*)    I(**)
 C,    J/K/mol=    8.110    4.157    4.157    5.048    5.046
 U,    kJ/mol =    2.541    1.239    1.239    1.779    1.770
 H,    kJ/mol =    2.541    1.239    1.239    1.779    1.770
 S,    J/K/mol=   13.428   17.763   17.562   17.293   17.093
 G,    kJ/mol =   -1.463   -4.057   -3.997   -3.377   -3.327
 U+ZPE,kJ/mol =    3.219    1.918    1.918    2.457    2.448
 H+ZPE,kJ/mol =    3.219    1.918    1.918    2.457    2.448
 G+ZPE,kJ/mol =   -0.785   -3.378   -3.318   -2.699   -2.648
 I(*)  - reduced moments of inertia are calculated by formula 1/I=1/Ia+1/Ib
 I(**) - reduced moments of inertia are calculated by Pitzer-Gwinn formulas
 Note: I(*)=I(**) for symmetric rotors.

Then, the total values of thermodynamic functions of the molecule are printed together with total energy values corrected for the total (electr+trans+rota+vibr+int.rot.) thermodynamic contributions.

 Total values of thermodynamic functions (T=  298.15 K,  P= 101325.00 Pa) 
 taking into account  1 internal rotations  (in different approximations)
----------------------------------------------------------------------------------------------------------------------
                Harmonic   Free Rotator   Pitzer-Gwinn tables
               Ocsillator  I(*)    I(**)     I(*)    I(**)
----------------------------------------------------------------------------------------------------------------------
 Cv, J/K/mol=   77.176   73.223   73.223   74.114   74.111
 Cp, J/K/mol=   85.490   81.537   81.537   82.428   82.426
 U,  kJ/mol =   76.986   75.007   75.007   76.225   76.215
 H,  kJ/mol =   79.465   77.486   77.486   78.704   78.694
 S,  J/K/mol=  318.525  322.860  322.659  322.390  322.190
 G,  kJ/mol =  -15.503  -18.775  -18.715  -17.417  -17.367
----------------------------------------------------------------------------------------------------------------------
I(*)  - reduced moments of inertia are calculated by formula 1/I=1/Ia+1/Ib
I(**) - reduced moments of inertia are calculated by Pitzer-Gwinn formulas
Note: Internal rotation contributions to U, H, G include U0=H0=ZPE
in HO and PG models (U0=H0=0 in FR model)


 *** Total energy corrected by TD functions (including internal rotations) ****
 Minimum electronic-nuclear energy was taken from the input file at step:   4
 Minimum Etot:    -665.26660848  (Please check the program decision manually!)

          Harmonic             Free Rotator               Pitzer-Gwinn tables
         Ocsillator        I(*)           I(**)          I(*)           I(**)
E      -665.26660848  -665.26660848  -665.26660848  -665.26660848  -665.26660848
E+ZPE  -665.24329545  -665.24329545  -665.24329545  -665.24329545  -665.24329545
E+U    -665.23728531  -665.23803928  -665.23803928  -665.23757538  -665.23757887
E+H    -665.23634110  -665.23709507  -665.23709507  -665.23663117  -665.23663466
E+G    -665.27251350  -665.27375972  -665.27373686  -665.27324249  -665.27322325

The values here are the results of total energy corrected by the contributions of internal rotation calculated at the current temperature and pressure ( program defaults: T=298.15K, P=101325Pa).

The file is finished with the thermodynamic functions calculated at different temperatures. As before, the temperature range can be set manually (default 0–500 K). Now, the internal rotation contributions are included. The WARNING’s are just a result of numerical errors during the interpolation of Pitzer-Gwinn tables for low temperatures for light molecule (the tables are given for the values of Qf large enough and their extrpolation to zero is frequently unrobust). Just skip the values with warnings. These values can be incorrect and should not be used. However, they have no effect on the remaining values.