MNDO AM1 PM3 PM5
Heat of formation 77 50 42 25 kJ mol"^1
Bond length 0.066 0.053 0.065 0.051 A ̊
Bond angle 6.298 5.467 5.708 5.413As of mid-2009 the latest version of the PMx series was PM6, which Stewart has
described in detail in a long paper [ 82 ]; in this paper, which also gives a brief
history of NDDO methods, it was explicitly said that PM4 and PM5 were “unpub-
lished”, presumably meaning that the details of their parameterization had not been
revealed. PM6 is available in Gaussian 09 [ 55 ], AMPAC 9 [ 57 ], and MOPAC2009
[ 58 ]. It appears to be a major improvement over PM3 and AM1 and will likely be
the standard general-purpose semiempirical method for some years, except in those
program suites which retain PM3 and AM1 without introducing PM6. A brief
summary of the performance of PM6, from the MOPAC2009 brochure [ 83 ]
(much more detail is given in [ 82 ], mainly for the parameterization for heats of
formation) indicates that this method:
- Was parameterized with data from over 9,000 compounds; experimental and
ab initio data were used, so unlikeearlierNDDOmethods(MNDO,AM1,
PM3; ca. 1975–1990) the parameterization is not purely empirical. Only about
500 compounds were used for PM3. - Gives better heats of formation (from tests on 1,373 compounds) than those from
B3LYP/6-31G (a DFT method), PM3, HF/6-31G, and AM1: the average
unsigned errors for PM6 and those four methods were 20.0 (PM6), 21.7, 26.2,
30.8, and 41.9 kJ mol"^1. Using a version of NDDO specially parameterized just
for heats of formation and somewhat more accurate for this purpose than PM6
(average unsigned errors 16.1 versus 20.0 kJ mol"^1 ), several errors were identi-
fied in a survey of ca. 1,300 compounds in the NIST Chemistry WebBook
database [ 84 ]. - Treats hydrogen bonds better than PM3 and AM1.
- Is parameterized for all main group and transition elements.
Some other information on the accuracy of PM6 is available from the
MOPAC2009 manual [ 85 ]:
PM6 PM3 AM1
Bond length 0.091 0.104 0.130 A ̊
Bond angle 7.86 8.50 8.77
Dipole moment 0.85 0.72 0.67 D
Ionization energy 0.50 0.68 0.63 eV6.2.5.7 SAM1
SAM1 (semi ab initio method number 1) was the last semiempirical method to be
reported (1993, [ 76 ]) by Dewar’s group. SAM1 is essentially a modification of
AM1 in which the two-electron integrals are calculated ab initio using contracted
6.2 The Basic Principles of SCF Semiempirical Methods 411