The text file is also avilable here


           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 61 charge: -0.292
 atom #   2 mmtype 31 charge:  1.229
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 11 charge: -0.292
 atom #   5 mmtype 11 charge: -0.292
 atom #   6 mmtype 61 charge: -0.292
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  5 charge:  0.038
 atom #  12 mmtype  5 charge:  0.000
 atom #  13 mmtype  5 charge:  0.000
 atom #  14 mmtype  5 charge:  0.000
 atom #  15 mmtype  5 charge:  0.000
 atom #  16 mmtype  5 charge:  0.000
 atom #  17 mmtype  5 charge:  0.000
 atom #  18 mmtype  5 charge:  0.000
 atom #  19 mmtype  5 charge:  0.000
 atom #  20 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy   -6.11
 STR   0.33 BND   1.52
 S-B   0.04  TOR  -6.12
 VDW   1.06  DIP/CHRG  -2.94
 Dipole Moment    2.60
 Heat of Formation      0.000 kcal/mole;
 Strain Energy      0.000


 start CAT - 0   Np                                              
0     * * * * * Energy is minimized within 0.0030 kcal * * * * *

         * * * * * MM2 energy is   -6.1098 kcal/mol * * * * *

               Accumulated movement is 0.0003 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
         3   C-C SP3-SP3                -0.004   -0.012         -49.200
         9   C-H ALIPHATIC              -3.205  -28.845         116.100
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         1   NEO (ALKANE)               -0.707   -0.707
         3   C(SP3)-METHYL              -1.510   -4.530
                                    ----------------   ---------------
                                         be =   -37.129   s =    66.400
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc         -40.839
       Strain Energy (energy+environment corrs.)=           -8.330


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy   -6.11
 STR   0.33 BND   1.53
 S-B   0.04  TOR  -6.12
 VDW   1.06  DIP/CHRG  -2.94
 Dipole Moment    2.60
 Incomplete heat of formation    -40.839 kcal/mole
 end CAT - 0   Np                                              

           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000
 generalized constants for angle   1   2   4  17   (type  61 31 35 20) are used
  0.000  0.000  0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 61 charge: -0.292
 atom #   2 mmtype 31 charge:  1.081
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 35 charge: -0.050
 atom #   5 mmtype 11 charge: -0.292
 atom #   6 mmtype 61 charge: -0.292
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  1 charge:  0.107
 atom #  12 mmtype  1 charge:  0.000
 atom #  13 mmtype  1 charge:  0.000
 atom #  14 mmtype  1 charge:  0.000
 atom #  15 mmtype  1 charge:  0.000
 atom #  16 mmtype  5 charge:  0.038
 atom #  17 mmtype 20 charge: -0.100
 atom #  18 mmtype 20 charge: -0.100
 atom #  19 mmtype  5 charge:  0.000
 atom #  20 mmtype  5 charge:  0.000
 atom #  21 mmtype  5 charge:  0.000
 atom #  22 mmtype  5 charge:  0.000
 atom #  23 mmtype  5 charge:  0.000
 atom #  24 mmtype  5 charge:  0.000
 atom #  25 mmtype  5 charge:  0.000
 atom #  26 mmtype  5 charge:  0.000
 atom #  27 mmtype  5 charge:  0.000
 atom #  28 mmtype  5 charge:  0.000
 atom #  29 mmtype  5 charge:  0.000
 atom #  30 mmtype  5 charge:  0.000
 atom #  31 mmtype  5 charge:  0.000
 atom #  32 mmtype  5 charge:  0.000
 atom #  33 mmtype  5 charge:  0.000
 atom #  34 mmtype  5 charge:  0.000
 atom #  35 mmtype  5 charge:  0.000
 atom #  36 mmtype  5 charge:  0.000
 atom #  37 mmtype  5 charge:  0.000
 atom #  38 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy  237.94
 STR 218.40 BND   9.96
 S-B   9.80  TOR  -7.93
 VDW   2.69  DIP/CHRG   5.02
 Dipole Moment    2.51
 Heat of Formation    -40.839 kcal/mole;
 Strain Energy     -8.330


 start CAT - 1E  Np                                              
0     * * * * * Energy is minimized within 0.0057 kcal * * * * *

         * * * * * MM2 energy is    5.0815 kcal/mol * * * * *

               Accumulated movement is 0.0618 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond 11-  4 does not have programmed enthalpy increments. 
         7   C-C SP3-SP3                -0.004   -0.028        -114.800
        20   C-H ALIPHATIC              -3.205  -64.100         258.000
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         2   NEO (ALKANE)               -0.707   -1.414
         6   C(SP3)-METHYL              -1.510   -9.060
                                    ----------------   ---------------
                                         be =   -77.637   s =   142.700
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc         -70.155
       Strain Energy (energy+environment corrs.)=           -0.018


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy    5.08
 STR   1.00 BND   3.61
 S-B  -0.09  TOR  -7.81
 VDW   2.31  DIP/CHRG   6.07
 Dipole Moment    2.15
 Incomplete heat of formation    -70.155 kcal/mole
 end CAT - 1E  Np                                              

           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000
 generalized constants for angle   1   2   6  17   (type  61 31 58 20) are used
  0.000  0.000  0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 61 charge: -0.292
 atom #   2 mmtype 31 charge:  1.081
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 11 charge: -0.292
 atom #   5 mmtype 11 charge: -0.292
 atom #   6 mmtype 58 charge: -0.050
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  1 charge:  0.107
 atom #  12 mmtype  1 charge:  0.000
 atom #  13 mmtype  1 charge:  0.000
 atom #  14 mmtype  1 charge:  0.000
 atom #  15 mmtype  1 charge:  0.000
 atom #  16 mmtype  5 charge:  0.038
 atom #  17 mmtype 20 charge: -0.100
 atom #  18 mmtype 20 charge: -0.100
 atom #  19 mmtype  5 charge:  0.000
 atom #  20 mmtype  5 charge:  0.000
 atom #  21 mmtype  5 charge:  0.000
 atom #  22 mmtype  5 charge:  0.000
 atom #  23 mmtype  5 charge:  0.000
 atom #  24 mmtype  5 charge:  0.000
 atom #  25 mmtype  5 charge:  0.000
 atom #  26 mmtype  5 charge:  0.000
 atom #  27 mmtype  5 charge:  0.000
 atom #  28 mmtype  5 charge:  0.000
 atom #  29 mmtype  5 charge:  0.000
 atom #  30 mmtype  5 charge:  0.000
 atom #  31 mmtype  5 charge:  0.000
 atom #  32 mmtype  5 charge:  0.000
 atom #  33 mmtype  5 charge:  0.000
 atom #  34 mmtype  5 charge:  0.000
 atom #  35 mmtype  5 charge:  0.000
 atom #  36 mmtype  5 charge:  0.000
 atom #  37 mmtype  5 charge:  0.000
 atom #  38 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy  225.37
 STR 213.24 BND   5.88
 S-B   5.05  TOR  -4.50
 VDW   0.80  DIP/CHRG   4.90
 Dipole Moment    2.77
 Heat of Formation    -70.155 kcal/mole;
 Strain Energy     -0.018


 start CAT - 1A  Np                                              
0     * * * * * Energy is minimized within 0.0057 kcal * * * * *

         * * * * * MM2 energy is    6.4709 kcal/mol * * * * *

               Accumulated movement is 0.0491 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond 11-  6 does not have programmed enthalpy increments. 
         7   C-C SP3-SP3                -0.004   -0.028        -114.800
        20   C-H ALIPHATIC              -3.205  -64.100         258.000
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         2   NEO (ALKANE)               -0.707   -1.414
         6   C(SP3)-METHYL              -1.510   -9.060
                                    ----------------   ---------------
                                         be =   -77.637   s =   142.700
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc         -68.766
       Strain Energy (energy+environment corrs.)=            1.371


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy    6.47
 STR   1.00 BND   3.46
 S-B  -0.09  TOR  -4.48
 VDW   0.70  DIP/CHRG   5.87
 Dipole Moment    2.06
 Incomplete heat of formation    -68.766 kcal/mole
 end CAT - 1A  Np                                              

           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000
 generalized constants for angle   1   2   4  22   (type  61 31 35 20) are used
  0.000  0.000  0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 61 charge: -0.292
 atom #   2 mmtype 31 charge:  0.932
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 35 charge: -0.050
 atom #   5 mmtype 35 charge: -0.050
 atom #   6 mmtype 61 charge: -0.292
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  1 charge:  0.107
 atom #  12 mmtype  1 charge:  0.000
 atom #  13 mmtype  1 charge:  0.000
 atom #  14 mmtype  1 charge:  0.000
 atom #  15 mmtype  1 charge:  0.000
 atom #  16 mmtype  1 charge:  0.107
 atom #  17 mmtype  1 charge:  0.000
 atom #  18 mmtype  1 charge:  0.000
 atom #  19 mmtype  1 charge:  0.000
 atom #  20 mmtype  1 charge:  0.000
 atom #  21 mmtype  5 charge:  0.038
 atom #  22 mmtype 20 charge: -0.100
 atom #  23 mmtype 20 charge: -0.100
 atom #  24 mmtype 20 charge: -0.100
 atom #  25 mmtype 20 charge: -0.100
 atom #  26 mmtype  5 charge:  0.000
 atom #  27 mmtype  5 charge:  0.000
 atom #  28 mmtype  5 charge:  0.000
 atom #  29 mmtype  5 charge:  0.000
 atom #  30 mmtype  5 charge:  0.000
 atom #  31 mmtype  5 charge:  0.000
 atom #  32 mmtype  5 charge:  0.000
 atom #  33 mmtype  5 charge:  0.000
 atom #  34 mmtype  5 charge:  0.000
 atom #  35 mmtype  5 charge:  0.000
 atom #  36 mmtype  5 charge:  0.000
 atom #  37 mmtype  5 charge:  0.000
 atom #  38 mmtype  5 charge:  0.000
 atom #  39 mmtype  5 charge:  0.000
 atom #  40 mmtype  5 charge:  0.000
 atom #  41 mmtype  5 charge:  0.000
 atom #  42 mmtype  5 charge:  0.000
 atom #  43 mmtype  5 charge:  0.000
 atom #  44 mmtype  5 charge:  0.000
 atom #  45 mmtype  5 charge:  0.000
 atom #  46 mmtype  5 charge:  0.000
 atom #  47 mmtype  5 charge:  0.000
 atom #  48 mmtype  5 charge:  0.000
 atom #  49 mmtype  5 charge:  0.000
 atom #  50 mmtype  5 charge:  0.000
 atom #  51 mmtype  5 charge:  0.000
 atom #  52 mmtype  5 charge:  0.000
 atom #  53 mmtype  5 charge:  0.000
 atom #  54 mmtype  5 charge:  0.000
 atom #  55 mmtype  5 charge:  0.000
 atom #  56 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy  175.91
 STR 148.92 BND  13.27
 S-B   7.33  TOR  -9.59
 VDW   4.83  DIP/CHRG  11.14
 Dipole Moment    1.58
 Heat of Formation    -68.766 kcal/mole;
 Strain Energy      1.371


 start CAT - 2EE Np                                              
0     * * * * * Energy is minimized within 0.0084 kcal * * * * *

         * * * * * MM2 energy is   17.2422 kcal/mol * * * * *

               Accumulated movement is 0.0355 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond 11-  4 does not have programmed enthalpy increments. 
 * * * * * error - bond 16-  5 does not have programmed enthalpy increments. 
        11   C-C SP3-SP3                -0.004   -0.044        -180.400
        31   C-H ALIPHATIC              -3.205  -99.355         399.900
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         3   NEO (ALKANE)               -0.707   -2.121
         9   C(SP3)-METHYL              -1.510  -13.590
                                    ----------------   ---------------
                                         be =  -118.145   s =   219.000
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc         -98.503
       Strain Energy (energy+environment corrs.)=            9.262


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy   17.24
 STR   1.91 BND   6.53
 S-B  -0.30  TOR  -9.33
 VDW   4.58  DIP/CHRG  13.84
 Dipole Moment    2.37
 Incomplete heat of formation    -98.503 kcal/mole
 end CAT - 2EE Np                                              

           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000
 generalized constants for angle   1   2   5  22   (type  61 31 35 20) are used
  0.000  0.000  0.000
 generalized constants for angle   1   2   6  24   (type  61 31 58 20) are used
  0.000  0.000  0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 61 charge: -0.292
 atom #   2 mmtype 31 charge:  0.932
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 11 charge: -0.292
 atom #   5 mmtype 35 charge: -0.050
 atom #   6 mmtype 58 charge: -0.050
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  1 charge:  0.107
 atom #  12 mmtype  1 charge:  0.000
 atom #  13 mmtype  1 charge:  0.000
 atom #  14 mmtype  1 charge:  0.000
 atom #  15 mmtype  1 charge:  0.000
 atom #  16 mmtype  1 charge:  0.107
 atom #  17 mmtype  1 charge:  0.000
 atom #  18 mmtype  1 charge:  0.000
 atom #  19 mmtype  1 charge:  0.000
 atom #  20 mmtype  1 charge:  0.000
 atom #  21 mmtype  5 charge:  0.038
 atom #  22 mmtype 20 charge: -0.100
 atom #  23 mmtype 20 charge: -0.100
 atom #  24 mmtype 20 charge: -0.100
 atom #  25 mmtype 20 charge: -0.100
 atom #  26 mmtype  5 charge:  0.000
 atom #  27 mmtype  5 charge:  0.000
 atom #  28 mmtype  5 charge:  0.000
 atom #  29 mmtype  5 charge:  0.000
 atom #  30 mmtype  5 charge:  0.000
 atom #  31 mmtype  5 charge:  0.000
 atom #  32 mmtype  5 charge:  0.000
 atom #  33 mmtype  5 charge:  0.000
 atom #  34 mmtype  5 charge:  0.000
 atom #  35 mmtype  5 charge:  0.000
 atom #  36 mmtype  5 charge:  0.000
 atom #  37 mmtype  5 charge:  0.000
 atom #  38 mmtype  5 charge:  0.000
 atom #  39 mmtype  5 charge:  0.000
 atom #  40 mmtype  5 charge:  0.000
 atom #  41 mmtype  5 charge:  0.000
 atom #  42 mmtype  5 charge:  0.000
 atom #  43 mmtype  5 charge:  0.000
 atom #  44 mmtype  5 charge:  0.000
 atom #  45 mmtype  5 charge:  0.000
 atom #  46 mmtype  5 charge:  0.000
 atom #  47 mmtype  5 charge:  0.000
 atom #  48 mmtype  5 charge:  0.000
 atom #  49 mmtype  5 charge:  0.000
 atom #  50 mmtype  5 charge:  0.000
 atom #  51 mmtype  5 charge:  0.000
 atom #  52 mmtype  5 charge:  0.000
 atom #  53 mmtype  5 charge:  0.000
 atom #  54 mmtype  5 charge:  0.000
 atom #  55 mmtype  5 charge:  0.000
 atom #  56 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy  163.15
 STR 146.71 BND   9.27
 S-B   2.49  TOR  -6.01
 VDW   0.65  DIP/CHRG  10.04
 Dipole Moment    3.76
 Heat of Formation    -98.503 kcal/mole;
 Strain Energy      9.262


 start CAT - 2AE Np                                              
0     * * * * * Energy is minimized within 0.0084 kcal * * * * *

         * * * * * MM2 energy is   14.2458 kcal/mol * * * * *

               Accumulated movement is 0.0307 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond 11-  5 does not have programmed enthalpy increments. 
 * * * * * error - bond 16-  6 does not have programmed enthalpy increments. 
        11   C-C SP3-SP3                -0.004   -0.044        -180.400
        31   C-H ALIPHATIC              -3.205  -99.355         399.900
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         3   NEO (ALKANE)               -0.707   -2.121
         9   C(SP3)-METHYL              -1.510  -13.590
                                    ----------------   ---------------
                                         be =  -118.145   s =   219.000
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc        -101.499
       Strain Energy (energy+environment corrs.)=            6.266


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy   14.25
 STR   1.72 BND   6.29
 S-B  -0.22  TOR  -5.90
 VDW   0.65  DIP/CHRG  11.70
 Dipole Moment    2.73
 Incomplete heat of formation   -101.499 kcal/mole
 end CAT - 2AE Np                                              

           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000
 generalized constants for angle   1   2   6  24   (type  58 31 58 20) are used
  0.000  0.000  0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 58 charge: -0.050
 atom #   2 mmtype 31 charge:  0.932
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 11 charge: -0.292
 atom #   5 mmtype 11 charge: -0.292
 atom #   6 mmtype 58 charge: -0.050
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  1 charge:  0.107
 atom #  12 mmtype  1 charge:  0.000
 atom #  13 mmtype  1 charge:  0.000
 atom #  14 mmtype  1 charge:  0.000
 atom #  15 mmtype  1 charge:  0.000
 atom #  16 mmtype  1 charge:  0.107
 atom #  17 mmtype  1 charge:  0.000
 atom #  18 mmtype  1 charge:  0.000
 atom #  19 mmtype  1 charge:  0.000
 atom #  20 mmtype  1 charge:  0.000
 atom #  21 mmtype 20 charge: -0.100
 atom #  22 mmtype 20 charge: -0.100
 atom #  23 mmtype  5 charge:  0.038
 atom #  24 mmtype 20 charge: -0.100
 atom #  25 mmtype 20 charge: -0.100
 atom #  26 mmtype  5 charge:  0.000
 atom #  27 mmtype  5 charge:  0.000
 atom #  28 mmtype  5 charge:  0.000
 atom #  29 mmtype  5 charge:  0.000
 atom #  30 mmtype  5 charge:  0.000
 atom #  31 mmtype  5 charge:  0.000
 atom #  32 mmtype  5 charge:  0.000
 atom #  33 mmtype  5 charge:  0.000
 atom #  34 mmtype  5 charge:  0.000
 atom #  35 mmtype  5 charge:  0.000
 atom #  36 mmtype  5 charge:  0.000
 atom #  37 mmtype  5 charge:  0.000
 atom #  38 mmtype  5 charge:  0.000
 atom #  39 mmtype  5 charge:  0.000
 atom #  40 mmtype  5 charge:  0.000
 atom #  41 mmtype  5 charge:  0.000
 atom #  42 mmtype  5 charge:  0.000
 atom #  43 mmtype  5 charge:  0.000
 atom #  44 mmtype  5 charge:  0.000
 atom #  45 mmtype  5 charge:  0.000
 atom #  46 mmtype  5 charge:  0.000
 atom #  47 mmtype  5 charge:  0.000
 atom #  48 mmtype  5 charge:  0.000
 atom #  49 mmtype  5 charge:  0.000
 atom #  50 mmtype  5 charge:  0.000
 atom #  51 mmtype  5 charge:  0.000
 atom #  52 mmtype  5 charge:  0.000
 atom #  53 mmtype  5 charge:  0.000
 atom #  54 mmtype  5 charge:  0.000
 atom #  55 mmtype  5 charge:  0.000
 atom #  56 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy  156.91
 STR 140.17 BND   5.50
 S-B   3.11  TOR  -2.76
 VDW   0.25  DIP/CHRG  10.65
 Dipole Moment    0.35
 Heat of Formation   -101.499 kcal/mole;
 Strain Energy      6.266


 start CAT - 2AA Np                                              
0     * * * * * Energy is minimized within 0.0084 kcal * * * * *

         * * * * * MM2 energy is   16.5926 kcal/mol * * * * *

               Accumulated movement is 0.0262 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond 11-  6 does not have programmed enthalpy increments. 
 * * * * * error - bond 16-  1 does not have programmed enthalpy increments. 
        11   C-C SP3-SP3                -0.004   -0.044        -180.400
        31   C-H ALIPHATIC              -3.205  -99.355         399.900
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         3   NEO (ALKANE)               -0.707   -2.121
         9   C(SP3)-METHYL              -1.510  -13.590
                                    ----------------   ---------------
                                         be =  -118.145   s =   219.000
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc         -99.152
       Strain Energy (energy+environment corrs.)=            8.613


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy   16.59
 STR   1.67 BND   5.32
 S-B  -0.22  TOR  -2.67
 VDW   0.21  DIP/CHRG  12.28
 Dipole Moment    0.31
 Incomplete heat of formation    -99.152 kcal/mole
 end CAT - 2AA Np                                              

           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000
 generalized constants for angle   1   2   4  27   (type  61 31 35 20) are used
  0.000  0.000  0.000
 generalized constants for angle   1   2   6  31   (type  61 31 58 20) are used
  0.000  0.000  0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 61 charge: -0.292
 atom #   2 mmtype 31 charge:  0.783
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 35 charge: -0.050
 atom #   5 mmtype 35 charge: -0.050
 atom #   6 mmtype 58 charge: -0.050
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  1 charge:  0.107
 atom #  12 mmtype  1 charge:  0.000
 atom #  13 mmtype  1 charge:  0.000
 atom #  14 mmtype  1 charge:  0.000
 atom #  15 mmtype  1 charge:  0.000
 atom #  16 mmtype  1 charge:  0.107
 atom #  17 mmtype  1 charge:  0.000
 atom #  18 mmtype  1 charge:  0.000
 atom #  19 mmtype  1 charge:  0.000
 atom #  20 mmtype  1 charge:  0.000
 atom #  21 mmtype  1 charge:  0.107
 atom #  22 mmtype  1 charge:  0.000
 atom #  23 mmtype  1 charge:  0.000
 atom #  24 mmtype  1 charge:  0.000
 atom #  25 mmtype  1 charge:  0.000
 atom #  26 mmtype  5 charge:  0.038
 atom #  27 mmtype 20 charge: -0.100
 atom #  28 mmtype 20 charge: -0.100
 atom #  29 mmtype 20 charge: -0.100
 atom #  30 mmtype 20 charge: -0.100
 atom #  31 mmtype 20 charge: -0.100
 atom #  32 mmtype 20 charge: -0.100
 atom #  33 mmtype  5 charge:  0.000
 atom #  34 mmtype  5 charge:  0.000
 atom #  35 mmtype  5 charge:  0.000
 atom #  36 mmtype  5 charge:  0.000
 atom #  37 mmtype  5 charge:  0.000
 atom #  38 mmtype  5 charge:  0.000
 atom #  39 mmtype  5 charge:  0.000
 atom #  40 mmtype  5 charge:  0.000
 atom #  41 mmtype  5 charge:  0.000
 atom #  42 mmtype  5 charge:  0.000
 atom #  43 mmtype  5 charge:  0.000
 atom #  44 mmtype  5 charge:  0.000
 atom #  45 mmtype  5 charge:  0.000
 atom #  46 mmtype  5 charge:  0.000
 atom #  47 mmtype  5 charge:  0.000
 atom #  48 mmtype  5 charge:  0.000
 atom #  49 mmtype  5 charge:  0.000
 atom #  50 mmtype  5 charge:  0.000
 atom #  51 mmtype  5 charge:  0.000
 atom #  52 mmtype  5 charge:  0.000
 atom #  53 mmtype  5 charge:  0.000
 atom #  54 mmtype  5 charge:  0.000
 atom #  55 mmtype  5 charge:  0.000
 atom #  56 mmtype  5 charge:  0.000
 atom #  57 mmtype  5 charge:  0.000
 atom #  58 mmtype  5 charge:  0.000
 atom #  59 mmtype  5 charge:  0.000
 atom #  60 mmtype  5 charge:  0.000
 atom #  61 mmtype  5 charge:  0.000
 atom #  62 mmtype  5 charge:  0.000
 atom #  63 mmtype  5 charge:  0.000
 atom #  64 mmtype  5 charge:  0.000
 atom #  65 mmtype  5 charge:  0.000
 atom #  66 mmtype  5 charge:  0.000
 atom #  67 mmtype  5 charge:  0.000
 atom #  68 mmtype  5 charge:  0.000
 atom #  69 mmtype  5 charge:  0.000
 atom #  70 mmtype  5 charge:  0.000
 atom #  71 mmtype  5 charge:  0.000
 atom #  72 mmtype  5 charge:  0.000
 atom #  73 mmtype  5 charge:  0.000
 atom #  74 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy   96.43
 STR  76.61 BND  10.19
 S-B   0.98  TOR  -7.23
 VDW   2.08  DIP/CHRG  13.80
 Dipole Moment    3.43
 Heat of Formation    -99.152 kcal/mole;
 Strain Energy      8.613


 start CAT - 3A  Np                                              
0     * * * * * Energy is minimized within 0.0111 kcal * * * * *

         * * * * * MM2 energy is   20.3653 kcal/mol * * * * *

               Accumulated movement is 0.0180 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond 11-  4 does not have programmed enthalpy increments. 
 * * * * * error - bond 16-  5 does not have programmed enthalpy increments. 
 * * * * * error - bond 21-  6 does not have programmed enthalpy increments. 
        15   C-C SP3-SP3                -0.004   -0.060        -246.000
        42   C-H ALIPHATIC              -3.205 -134.610         541.800
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         4   NEO (ALKANE)               -0.707   -2.828
        12   C(SP3)-METHYL              -1.510  -18.120
                                    ----------------   ---------------
                                         be =  -158.653   s =   295.300
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc        -135.888
       Strain Energy (energy+environment corrs.)=            9.505


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy   20.37
 STR   2.58 BND   7.93
 S-B  -0.43  TOR  -7.05
 VDW   1.88  DIP/CHRG  15.46
 Dipole Moment    3.03
 Incomplete heat of formation   -135.888 kcal/mole
 end CAT - 3A  Np                                              

           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000
 generalized constants for angle   1   2   4  29   (type  58 31 35 20) are used
  0.000  0.000  0.000
 generalized constants for angle   1   2   6  31   (type  58 31 58 20) are used
  0.000  0.000  0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 58 charge: -0.050
 atom #   2 mmtype 31 charge:  0.783
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 35 charge: -0.050
 atom #   5 mmtype 11 charge: -0.292
 atom #   6 mmtype 58 charge: -0.050
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  1 charge:  0.107
 atom #  12 mmtype  1 charge:  0.000
 atom #  13 mmtype  1 charge:  0.000
 atom #  14 mmtype  1 charge:  0.000
 atom #  15 mmtype  1 charge:  0.000
 atom #  16 mmtype  1 charge:  0.107
 atom #  17 mmtype  1 charge:  0.000
 atom #  18 mmtype  1 charge:  0.000
 atom #  19 mmtype  1 charge:  0.000
 atom #  20 mmtype  1 charge:  0.000
 atom #  21 mmtype  1 charge:  0.107
 atom #  22 mmtype  1 charge:  0.000
 atom #  23 mmtype  1 charge:  0.000
 atom #  24 mmtype  1 charge:  0.000
 atom #  25 mmtype  1 charge:  0.000
 atom #  26 mmtype 20 charge: -0.100
 atom #  27 mmtype 20 charge: -0.100
 atom #  28 mmtype  5 charge:  0.038
 atom #  29 mmtype 20 charge: -0.100
 atom #  30 mmtype 20 charge: -0.100
 atom #  31 mmtype 20 charge: -0.100
 atom #  32 mmtype 20 charge: -0.100
 atom #  33 mmtype  5 charge:  0.000
 atom #  34 mmtype  5 charge:  0.000
 atom #  35 mmtype  5 charge:  0.000
 atom #  36 mmtype  5 charge:  0.000
 atom #  37 mmtype  5 charge:  0.000
 atom #  38 mmtype  5 charge:  0.000
 atom #  39 mmtype  5 charge:  0.000
 atom #  40 mmtype  5 charge:  0.000
 atom #  41 mmtype  5 charge:  0.000
 atom #  42 mmtype  5 charge:  0.000
 atom #  43 mmtype  5 charge:  0.000
 atom #  44 mmtype  5 charge:  0.000
 atom #  45 mmtype  5 charge:  0.000
 atom #  46 mmtype  5 charge:  0.000
 atom #  47 mmtype  5 charge:  0.000
 atom #  48 mmtype  5 charge:  0.000
 atom #  49 mmtype  5 charge:  0.000
 atom #  50 mmtype  5 charge:  0.000
 atom #  51 mmtype  5 charge:  0.000
 atom #  52 mmtype  5 charge:  0.000
 atom #  53 mmtype  5 charge:  0.000
 atom #  54 mmtype  5 charge:  0.000
 atom #  55 mmtype  5 charge:  0.000
 atom #  56 mmtype  5 charge:  0.000
 atom #  57 mmtype  5 charge:  0.000
 atom #  58 mmtype  5 charge:  0.000
 atom #  59 mmtype  5 charge:  0.000
 atom #  60 mmtype  5 charge:  0.000
 atom #  61 mmtype  5 charge:  0.000
 atom #  62 mmtype  5 charge:  0.000
 atom #  63 mmtype  5 charge:  0.000
 atom #  64 mmtype  5 charge:  0.000
 atom #  65 mmtype  5 charge:  0.000
 atom #  66 mmtype  5 charge:  0.000
 atom #  67 mmtype  5 charge:  0.000
 atom #  68 mmtype  5 charge:  0.000
 atom #  69 mmtype  5 charge:  0.000
 atom #  70 mmtype  5 charge:  0.000
 atom #  71 mmtype  5 charge:  0.000
 atom #  72 mmtype  5 charge:  0.000
 atom #  73 mmtype  5 charge:  0.000
 atom #  74 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy   88.14
 STR  72.68 BND   8.07
 S-B   1.21  TOR  -4.28
 VDW  -2.69  DIP/CHRG  13.16
 Dipole Moment    2.27
 Heat of Formation   -135.888 kcal/mole;
 Strain Energy      9.505


 start CAT - 3E  Np                                              
0     * * * * * Energy is minimized within 0.0111 kcal * * * * *

         * * * * * MM2 energy is   16.7024 kcal/mol * * * * *

               Accumulated movement is 0.0199 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond 11-  4 does not have programmed enthalpy increments. 
 * * * * * error - bond 16-  6 does not have programmed enthalpy increments. 
 * * * * * error - bond 21-  1 does not have programmed enthalpy increments. 
        15   C-C SP3-SP3                -0.004   -0.060        -246.000
        42   C-H ALIPHATIC              -3.205 -134.610         541.800
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         4   NEO (ALKANE)               -0.707   -2.828
        12   C(SP3)-METHYL              -1.510  -18.120
                                    ----------------   ---------------
                                         be =  -158.653   s =   295.300
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc        -139.551
       Strain Energy (energy+environment corrs.)=            5.842


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy   16.70
 STR   2.30 BND   7.46
 S-B  -0.35  TOR  -4.13
 VDW  -2.82  DIP/CHRG  14.24
 Dipole Moment    1.64
 Incomplete heat of formation   -139.551 kcal/mole
 end CAT - 3E  Np                                              

           The following torsional parameters are read in
                   (* for 4-membered ring)
               atom type nos.     v1      v2      v3
               1   2  31  11     0.000   1.500   0.000
               5   2  31  11     0.000   1.500   0.000
               1   2  31  61     0.000  -1.500   0.000
               5   2  31  61     0.000  -1.500   0.000
               1  35  31  11     0.000   1.000   0.000
               1  35  31  61     0.000  -1.000   0.000
               1  58  31  11     0.500  -1.000   0.500
               1  58  31  61     0.000   1.000   0.000
 generalized constants for angle   1   2   4  34   (type  58 31 35 20) are used
  0.000  0.000  0.000
 generalized constants for angle   1   2   6  38   (type  58 31 58 20) are used
  0.000  0.000  0.000


          The following  stretching parameters are read in
               bond type    k(s)      l(0)         l(t2)
               11 -  31    3.000     1.8000     0.0000
               31 -  61    3.000     1.8000     0.0000
 atom #   1 mmtype 58 charge: -0.050
 atom #   2 mmtype 31 charge:  0.635
 atom #   3 mmtype  2 charge: -0.101
 atom #   4 mmtype 35 charge: -0.050
 atom #   5 mmtype 35 charge: -0.050
 atom #   6 mmtype 58 charge: -0.050
 atom #   7 mmtype  1 charge:  0.000
 atom #   8 mmtype  1 charge:  0.000
 atom #   9 mmtype  1 charge:  0.000
 atom #  10 mmtype  1 charge:  0.000
 atom #  11 mmtype  1 charge:  0.107
 atom #  12 mmtype  1 charge:  0.000
 atom #  13 mmtype  1 charge:  0.000
 atom #  14 mmtype  1 charge:  0.000
 atom #  15 mmtype  1 charge:  0.000
 atom #  16 mmtype  1 charge:  0.107
 atom #  17 mmtype  1 charge:  0.000
 atom #  18 mmtype  1 charge:  0.000
 atom #  19 mmtype  1 charge:  0.000
 atom #  20 mmtype  1 charge:  0.000
 atom #  21 mmtype  1 charge:  0.107
 atom #  22 mmtype  1 charge:  0.000
 atom #  23 mmtype  1 charge:  0.000
 atom #  24 mmtype  1 charge:  0.000
 atom #  25 mmtype  1 charge:  0.000
 atom #  26 mmtype  1 charge:  0.107
 atom #  27 mmtype  1 charge:  0.000
 atom #  28 mmtype  1 charge:  0.000
 atom #  29 mmtype  1 charge:  0.000
 atom #  30 mmtype  1 charge:  0.000
 atom #  31 mmtype 20 charge: -0.100
 atom #  32 mmtype 20 charge: -0.100
 atom #  33 mmtype  5 charge:  0.038
 atom #  34 mmtype 20 charge: -0.100
 atom #  35 mmtype 20 charge: -0.100
 atom #  36 mmtype 20 charge: -0.100
 atom #  37 mmtype 20 charge: -0.100
 atom #  38 mmtype 20 charge: -0.100
 atom #  39 mmtype 20 charge: -0.100
 atom #  40 mmtype  5 charge:  0.000
 atom #  41 mmtype  5 charge:  0.000
 atom #  42 mmtype  5 charge:  0.000
 atom #  43 mmtype  5 charge:  0.000
 atom #  44 mmtype  5 charge:  0.000
 atom #  45 mmtype  5 charge:  0.000
 atom #  46 mmtype  5 charge:  0.000
 atom #  47 mmtype  5 charge:  0.000
 atom #  48 mmtype  5 charge:  0.000
 atom #  49 mmtype  5 charge:  0.000
 atom #  50 mmtype  5 charge:  0.000
 atom #  51 mmtype  5 charge:  0.000
 atom #  52 mmtype  5 charge:  0.000
 atom #  53 mmtype  5 charge:  0.000
 atom #  54 mmtype  5 charge:  0.000
 atom #  55 mmtype  5 charge:  0.000
 atom #  56 mmtype  5 charge:  0.000
 atom #  57 mmtype  5 charge:  0.000
 atom #  58 mmtype  5 charge:  0.000
 atom #  59 mmtype  5 charge:  0.000
 atom #  60 mmtype  5 charge:  0.000
 atom #  61 mmtype  5 charge:  0.000
 atom #  62 mmtype  5 charge:  0.000
 atom #  63 mmtype  5 charge:  0.000
 atom #  64 mmtype  5 charge:  0.000
 atom #  65 mmtype  5 charge:  0.000
 atom #  66 mmtype  5 charge:  0.000
 atom #  67 mmtype  5 charge:  0.000
 atom #  68 mmtype  5 charge:  0.000
 atom #  69 mmtype  5 charge:  0.000
 atom #  70 mmtype  5 charge:  0.000
 atom #  71 mmtype  5 charge:  0.000
 atom #  72 mmtype  5 charge:  0.000
 atom #  73 mmtype  5 charge:  0.000
 atom #  74 mmtype  5 charge:  0.000
 atom #  75 mmtype  5 charge:  0.000
 atom #  76 mmtype  5 charge:  0.000
 atom #  77 mmtype  5 charge:  0.000
 atom #  78 mmtype  5 charge:  0.000
 atom #  79 mmtype  5 charge:  0.000
 atom #  80 mmtype  5 charge:  0.000
 atom #  81 mmtype  5 charge:  0.000
 atom #  82 mmtype  5 charge:  0.000
 atom #  83 mmtype  5 charge:  0.000
 atom #  84 mmtype  5 charge:  0.000
 atom #  85 mmtype  5 charge:  0.000
 atom #  86 mmtype  5 charge:  0.000
 atom #  87 mmtype  5 charge:  0.000
 atom #  88 mmtype  5 charge:  0.000
 atom #  89 mmtype  5 charge:  0.000
 atom #  90 mmtype  5 charge:  0.000
 atom #  91 mmtype  5 charge:  0.000
 atom #  92 mmtype  5 charge:  0.000


          The following vdw parameters are read in
               atom type    epsilon    radius lpde ihtyp ihdonr
                   61        1.650     0.0780       0       0       0


          The following bending parameters are read in
                   (* for 4-membered ring)
                   (+ for 3-membered ring)

               atom types     k(b)   theta(0)   ed. type
                 2 31 11     0.500   109.500       0   
                 2 31 61     0.500   105.000       0   
                11 31 11     0.300   141.500       0   
                11 31 61     0.300    84.000       0   
                61 31 61     0.300   147.000       0   
                11 31 35     0.250   137.000       0   
                11 31 58     0.250    85.000       0   
                35 31 61     0.210    85.000       0   
                58 31 61     0.400   160.000       0   


 MMX Energy   17.32
 STR   3.13 BND   9.80
 S-B  -0.58  TOR  -6.15
 VDW  -2.20  DIP/CHRG  13.33
 Dipole Moment    0.26
 Heat of Formation   -139.551 kcal/mole;
 Strain Energy      5.842


 start CAT - 4   Np                                              
0     * * * * * Energy is minimized within 0.0138 kcal * * * * *

         * * * * * MM2 energy is   17.3201 kcal/mol * * * * *

               Accumulated movement is 0.0006 ang/atom


       ------------------------------------------------------------
       Heat of Formation, Strain Energies and Entropies at 300 k
        (units are kcal or eu.)
       Bond Enthalpy (be) and Entropy:
         #   Bond or Structure          Each    Total     Tot S contrib.
 * * * * * error - bond  2-  1 does not have programmed enthalpy increments. 
 * * * * * error - bond  3-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  4-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  5-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond  6-  2 does not have programmed enthalpy increments. 
 * * * * * error - bond 11-  4 does not have programmed enthalpy increments. 
 * * * * * error - bond 16-  5 does not have programmed enthalpy increments. 
 * * * * * error - bond 21-  6 does not have programmed enthalpy increments. 
 * * * * * error - bond 26-  1 does not have programmed enthalpy increments. 
        19   C-C SP3-SP3                -0.004   -0.076        -311.600
        53   C-H ALIPHATIC              -3.205 -169.865         683.700
         1   C-C SP2-SP3                 0.170    0.170         -14.300
         1   C-H OLEFINIC               -3.205   -3.205          13.800
         5   NEO (ALKANE)               -0.707   -3.535
        15   C(SP3)-METHYL              -1.510  -22.650
                                    ----------------   ---------------
                                         be =  -199.161   s =   371.600
 3 & 4 Ring corrections to entropy are included w/o symmetry corrections.
 for each 5-ring add 26 eu.; for each 6 &7-ring add 16 eu.;
 for each 8-ring add 14 eu.; for higher rings add 12 eu. each.
 there are no symmetry corrections to the entropy.


 Heat of Formation calculation:
       Partition Function Contribution (PFC)
          Conformational Population Increment (POP)  0.000
          Torsional Contribution (TOR)               0.000
          Translation/Rotation Term (T/R)            2.400
                                             -------------
                                              PFC =  2.400

       Heat of Formation (hf0) = energy + be + pfc        -179.441
       Strain Energy (energy+environment corrs.)=            3.580


 CAUTION, delta hf is not correct because of missing parameters.

  Use total energy or strain energy to compare the stabilities of conformers
  and diastereomers.  Caution, energy parameters for metal systems are
  generalized and may not represent a particular metal or oxidation state.
  Use heats of formation to compare stabilities of structural isomers like
  acetaldehyde and enol or allyl chloride and cyclopropyl chloride.  Many
  bond contributions to the heat of formation are unknown-these contribute
  0.0 to the value given.


 MMX Energy   17.32
 STR   3.13 BND   9.81
 S-B  -0.58  TOR  -6.16
 VDW  -2.21  DIP/CHRG  13.33
 Dipole Moment    0.26
 Incomplete heat of formation   -179.441 kcal/mole
 end CAT - 4   Np                                              


 MMX Energy   17.32
 STR   3.13 BND   9.81
 S-B  -0.58  TOR  -6.16
 VDW  -2.21  DIP/CHRG  13.33
 Dipole Moment    0.26
 Incomplete heat of formation   -179.441 kcal/mole
 end CAT - 4   Np                                              
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