Summary: NBO for transition metal

[Jerry C C Chan <jerry;at;dft.chem.cuhk.hk>]

 Dear Netters,
         Some days ago I posted a message below:
 >       I notice that NBO has already been applied to transition metal
 > containing systems.  Could anybody give me some references which concern
 > the transition metal-ligand interaction using NBO analysis, in addition to
 > the work by Maseras and Morokuma CPL 1992.
 >       I have tried applying NBO analysis to [Co(NH3)5Cl]2+ and I find
 > some difficulties in interpretating some of the results:
 > if LP ( 1) N 3 / BD*( 1)Co 1-Cl 2, "lone pair electrons of N (donor) /
 > antibonding orbital of Co-Cl (acceptor)", is interpreted as an
 > indication of the importance of the resonance N-Co <-> N(+)-Co Cl(-),
 how
 > should one interprete BD ( 1)Co 1-Cl 2 / RY*(16)Co 1 ?
         I would like to express my gratitude to all who response to my
 query.  Special thanks are due to Profs. Frank Weinhold, Jay Badenhoop,
 Martin Kaupp and Eric Glendening.  I wish my summary would contribute to
 the popularity of NBO analysis.
 *************
 > 1.  Is it justified if NBO scheme is used to analyze the SCF density
 > obtained by dft method?
 While not developed for DFT wavefunctions, NBO analyzes the 1st order
 density matrix, and therefore should be more compatible with density-
 based methods than methods which analyze the wavefunction to determine
 bond order.  We have had much success (and yes, some surprising results
 which were found later to be consistent with experimental results)
 from NBO analysis of coordination complexes.
 > 2.  Is there any physical meaning associated with the energy of the
 > natural bonding orbital?  I don't understand the physical picture of
 > "Population inversion found on atom ..." although there is an
 > operational explanation in the NBO manual.
 The natural bond orbitals are calculated as the 1- and 2-center set
 of orthogonal orbitals which takes account of the greatest amount of
 the electron density in a maximum-occupancy sense.  Each orbital
 has an energy or eigenvalue associated with it, just as the atomic
 orbitals and molecular orbitals do.  However, sometimes one or more
 orbitals will be higher in occupancy, but also higher in energy than
 one or more other orbitals.  Therefore the ordering from highest to
 lowest occupancy and the ordering from lowest to highest energy will
 not be the same.  Often this occurs if you have a large number of
 orbitals which are fairly close in energy and population, which is
 common in these coordination complexes.  This warning message about
 "population inversion" just alerts you to this different ordering of
 the orbitals, and does not indicate the orbitals are of inferior
 quality or are mislabeled in any way.
 > 3.  How can the NBO result be considered as valid?  NHO procedure
 > fail in CO2 (JACS, 1980) because of the miscount of the total number
 > of orbitals.  However, if the total number of orbitals is counted
 > correctly but some of the BD and *BD occupancy are < 1.7 and > 0.4,
 > respectively, can we still accept the NBO result?
 First, the NBO procedure has been modified to handle a wider variety of
 cases than in 1980.  I do not believe that the CO2 case fails with the
 latest version of NBO. ... However, you must not just consider the NBO's
 listed in the table.  This is the "best"  localized set of orbitals,
 but
 low-occupancy bonding orbitals (BD or LP) or high-occupancy anti-bonds
 (BD*) indicates a highly delocalized molecule.  You must also consider the
 list of second order perturbative estimates of the donor-acceptor
 interactions.  This list indicates the most important delocalizations from
 bonding to antibonding orbitals. You will find both Co --> ligand and
 backbonding ligand --> Co interactions.
  ...
 In addition, our group has developed a quantitative NBO-based resonance
 theory, which calculates a set of localized resonance structures and
 associated resonance weights which best describe the full density,
 then calculates not only a bond order but also partitions the bond
 into covalent and ionic contributions to this bond order based on
 the bond polarization coefficients.  This bond order is more comparable
 to Bader's bond order than a measure of bond order only based on the
 "best" localized NBO structure (resonance structure of highest
 "weight")
 only.  Unfortunately, the method has been developed for organic
 molecules, and cannot handle transition metal complexes without further
 development.
 Jay Badenhoop
 Department of Chemistry
 Southern Illinois University at Carbondale
 *******************
 >        In the Second Order Perturbative Analysis of Co(NH3)5H2O, I get
 >  BD*( 1)Co 1- N 4     /299. BD*( 1)Co 1- N 5      2168.13    0.01    0.249
 > I really do not understand the physical picture implied by these large >
 interactions.
 The BD*-BD* 2nd-order energies should be ignored, since the BD* is
 not even approximately "doubly occupied" and the PT picture is no
 longer
 valid.  (NBO prints out these entries for convenience in analyzing
 excited states, which may have significant population in BD* orbitals.)
 Only the donor(LP,BD)-acceptor(BD*,RY*) entries have physical significance
 in this case.  FW
 *******************
 > 	I notice that NBO has already been applied to transition metal
 > containing systems.  Could anybody give me some references which concern
 > the transition metal-ligand interaction using NBO analysis, in addition
 > to the work by Maseras and Morokuma CPL 1992.
 >
 We frequently use the NPA, and to a lesser extent the NBO analysis for
 TM compounds. Some references are: Inorg. Chem. 1994,33,2122; Chem.Eur.J.
 1996,2,348; J.Am.Chem.Soc. 1996,118,3018.
 > 	I have tried applying NBO analysis to [Co(NH3)5Cl]2+ and I find
 > some difficulties in interpretating some of the results:
 >
 One principle problem with the NBO part is that for many TM compounds the
 program fails to find _one_ Lewis structure. Thus, you should be very
 careful in examining the Lewis structure you get. Does it make any
 chemical sense? How large are, e.g., the energy terms in the second-order
 perturbation theory analysis (values larger than, say, 30-50 kcal/Mol
 clearly tell you that your Lewis structure does not describe the density
 matrix well) ? Of course there are other criteria one may look at, such as
 the percentage of the density matrix described by the Lewis structure.
 To get around these problems, Weinhold and coworkers have meanwhile
 developed an extension they call 'natural resonance theory' which expands
 the density matrix in several NBO Lewis structures. While the theory is,
 as far as I know, at the moment just available as an internal report of
 the University of Wisconsin, some interesting applications (to main group
 species) may be found in: J. Chem. Educ. 1995, 72, 583. I expect this to
 give a much improved analysis for TM systems as well and hope it will be
 available soon (it's now part of the NBO 4.0 program).
 Of course the NPA is no problem, so charges and NAO populations may be used
 safely even with the present version.
 One point regards the use of NBO/NPA with DFT (Kohn-Sham) calculations: In
 principle the Kohn-Sham orbitals only describe a wavefunction for the
 so-called 'noninteracting reference system' and thus can not be
 interpreted as the wavefunction for the real system. In practice, however,
 this does not create any problems. Comparisons with HF, MP2, etc....
 density matrices show that the KS orbitals give the expected
 characteristics (e.g. showing effects of electron correlation) and we have
 found them to provide a useful basis for qualitative interpretations, in
 particular for TM systems.
 Hope this helps a bit.
 Regards, Martin Kaupp
 ------------------------------------------------------------------
 | Dr. Martin Kaupp                                               |
 | Max-Planck-Institut fuer Festkoerperforschung,                 |
 | Heisenbergstrasse 1, D-70569 Stuttgart, Germany,               |
 | Tel.: country-code+711/689-1532                                |
 | Fax.: country-code+711/689-1562                                |
 | email: kaupp;at;vsibm1.mpi-stuttgart.mpg.de                       |
 |                                                                |
 | and Institut fuer Theoretische Chemie, Universitaet Stuttgart, |
 | Pfaffenwaldring 55, D-70569 Stuttgart, Germany                 |
 | Tel.: country-code+711/685-4399                                |
 | Fax.: country-code+711/685-4442                                |
 | http://www.theochem.uni-stuttgart.de/~kaupp/
 |
 ------------------------------------------------------------------
 ************************
 The Co-Cl bond that NBO calculates is probably highly polarized
 toward Cl and might alternatively be described as a Cl lone pair
 with fairly strong charge transfer interaction with Co.  The
 interaction is apparently strong enough that NBO calculates a
 bond between these two atoms.  Co-Cl --> RY*(16) is then a
 separate charge transfer interaction between the Cl lone pair
 and a different hybrid on Co (presumably one of the 3d orbitals?).
 I gather that you're using the NBO perturbative analysis to
 judge the degree of delocalization between the ligands and Co.
 If so, you should probably force NBO to treat the ligands
 consistently.  That is, if NBO doesn't calculate any bonds
 between Co and NH3, then prevent the program for calculating a
 Co-Cl bond.  This is accomplished with NBO $CHOOSE keylist,
 which is described in the NBO manual.  $CHOOSE allows the user
 to stipulate the pattern of bonds (the Lewis structure) that
 NBO will calculate.  For your complex, only ask for NH bonds;
 no bonds would then be calculated between Co and N or Cl.
 If you don't have an NBO manual and would like to try $CHOOSE,
 send me a copy of your input deck.  I'll add the $CHOOSE keylist
 to it (it's fairly simple) and return the file to you.
 Eric Glendening
 Department of Chemistry
 Indiana State University
 Terre Haute, IN  47809
 ericg;at;chem.indstate.edu
 **************************
 The rule of thumb that I use is to neglect any interaction that
 is an order of magnitude weaker than the strongest appearing in
 NBO's perturbative analysis.  This works well whenever one is
 looking for a qualitative description of the delocalization
 patterns in a molecule (or complex, as in your case).  So I'd
 ignore the RY* interaction.
  ...
 It is certainly reasonable to judge the degree of covalent character
 from the presence or absence of a bonding NBO.  If NBO calculates a
 bond, then the polarization coefficients give a quantitative measure
 of covalent character; if NBO calculates a lone pair, then covalency
 can be judged from the strength of the orbital interactions.  You won't
 however be able to compare the covalency of two interactions when NBO
 assigns one a bond and the other a lone pair.  While it is likely that
 the interaction with the bonding NBO should have higher covalent
 character, this may not always be the case.  I really recommend
 $CHOOSE as it will allow a consistent comparison of all interactions
 based on lone pair delocalizations.
 Eric Glendening
 ************************
 [Co(NH3)5Cl]2+
  CO   0.00000     0.00000     0.00000
  CL  -1.72778    -0.00000    -1.47168
  N    1.47849     0.00000     1.27277
  N    1.25572    -0.00000    -1.50461
  N   -0.03050    -1.96150    -0.01613
  N   -0.03050     1.96150    -0.01613
  N   -1.27561     0.00000     1.51536
  H    1.15559     0.00000     2.23183
  H    2.07308     0.81190     1.16605 ...
 Here's the CHOOSE input for your Co complex:
  $nbo  $end
  $choose
     lone  1 3  2 4  3 1  4 1  5 1  6 1  7 1  end
     bond  s 3  8   s 3  9   s 3 10
           s 4 11   s 4 12   s 4 13
           s 5 14   s 5 15   s 5 16
           s 6 17   s 6 18   s 6 19
           s 7 20   s 7 21   s 7 22  end
  $end
 Note that the "resonance" keyword is not needed when the Lewis
 structure is specified in $choose.  $choose is free-format and
 reads as follows:
 First the lone pairs (lone ... end); atom 1 (Co) has 3, atom 2
 (Cl) has 4, etc.
 Then the bonds (bond ... end); a single bond between atoms 3 and
 8, a single bond between atoms 3 and 9, etc.
 Attach the $choose...$end input to the end of your input deck and
 run; no need to modify your input deck in any other way.  NBO always
 searches the input deck for $choose and uses it if available.
 Otherwise, NBO defaults to its standard search for a Lewis structure.
 Also, $choose input will in no way affect the population analysis.
 Just run NBO once; you'll get the atomic charges and $choose Lewis
 structure in one calculation.
 Eric
 *************************
 From WEINHOLD;at;chem.wisc.eduThu May  2 08:35:05 1996
 Date: Mon, 29 Apr 96 11:44 CST
 From: WEINHOLD;at;chem.wisc.edu
 To: jerry;at;dft
 Subject: Re: NBO
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