Posts Tagged ‘lowest energy pose’

A molecular balance for dispersion energy?

Sunday, February 7th, 2016

The geometry of cyclo-octatetraenes differs fundamentally from the lower homologue benzene in exhibiting slow (nuclear) valence bond isomerism rather than rapid (electronic) bond-equalising resonance. In 1992 Anderson and Kirsch[1] exploited this property to describe a simple molecular balance for estimating how two alkyl substituents on the ring might interact via the (currently very topical) mechanism of dispersion (induced-dipole-induced-dipole) attractions. These electron correlation effects are exceptionally difficult to model using formal quantum mechanics and are nowadays normally replaced by more empirical functions such as Grimme's D3BJ correction.[2] Here I explore aspects of how the small molecule below might be used to investigate the accuracy of such estimates of dispersion energies.

bu

The concentration of the two forms shown above can be readily estimated by NMR spectroscopy (the barrier is slow enough to allow peaks for both isomers to be integrated). This shows that the 1,6 form is present in greater concentrations than the 1,4 form, equivalent to a difference in free energy ΔΔG298 of 0.39 kcal/mol in favour of the former. Why is this? Because, it is claimed,  in the 1,6 isomer the two t-butyl groups are close enough to experience mutual dispersion attractions not experienced by the 1,4 form. This can be illustrated using the NCI display below for the two forms.

Click for 3D. Addition NCI interactions ringed in red.

Click for 3D. 1,6-isomer: Additional NCI interactions ringed in red.

Click for 3D

Click for 3D, 1,4 isomer.

Method Equilibrium constant, 298K ΔΔE ΔΔH298 ΔΔS298 ΔΔG298 Source
Experiment 1.93 1.14 -2.5 0.387 [1]
B3LYP/Def2-TZVPP/CDCl3 (no dispersion) 1.906 0.05 0.00 +1.3 0.382 [3],[4]
B3LYP/Def2-TZVPP/CDCl3 (gd3bj dispersion) 8.36 0.75 0.66 +2.0 1.25 [5],[6]

This contains a contribution of RTLn 2 (= 0.410 kcal/mol = 1.04 in ΔS), where 2 is the symmetry number for a species with C2 rotational symmetry, to the 1,4-isomer only.

The interpretation of these results, as is often found, is non-trivial.

  1. The relative concentrations of species in equilibrium equates with their relative free energies, ΔG298 and not ΔE (the difference in total energy computed using either quantum or molecular mechanics).
  2. ΔG298  has a component derived from the entropy of the system, and this in turn has contributions from symmetry (numbers).  Only the 1,6-isomer has two-fold rotational symmetry for the lowest energy pose of the two t-butyl groups, and this contributes 0.41 kcal/mol to ΔG298. This aspect is not discussed in the original article.[1]
  3. The B3LYP/Def2-TZVPP DFT method predicts ΔΔE to be +0.05 kcal/mol without the inclusion of the D3BJ dispersion correction but +0.75 kcal/mol with. One might approximately equate the latter to the contributions ringed in red in the NCI distributions shown above. The enthalpies (where ΔΔE is corrected for zero point energies) are very similar.
  4. Conversion to ΔG298 involves use of the vibrational frequencies to obtain the entropy; here one encounters a difference between the two double bond isomers. The lowest energy vibration for C2-symmetric 1,4 is 23 cm-1, whereas that for the 1,6 is only 7 cm-1 (a value which also depends on round-off errors and accuracies in the calculation). These errors in the RRHO (rigid-rotor-harmonic-oscillator) approximations makes meaningful calculation of ΔS298 and hence ΔG298 problematic at this small energy difference level. In both cases, this approach suggests that the entropy of the 1,6 form is slightly larger than the 1,4 isomer, whereas the reverse is apparently true by experimental measurement. It might all boil down to those low-frequency vibrations!

So we may conclude that whereas the dispersion uncorrected method gets the right answer for the equilibrium constant for probably the wrong reasons, inclusion of a dispersion correction would get the right answer were it not for the error in the entropy. Agreement with experiment would be obtained if the calculated entropy difference were to be -0.9 kcal/mol K-1 instead of +2.0. Thus the 1,6 isomer has the two t-butyl groups weakly interacting (red circle above), which intuition tends to suggest would reduce the entropy (reduce the disorder) of the system and not increase it. 

At least in this relatively small molecule, we now have a handle for estimating these sorts of effects in terms of variables such as the basis set used, the energy Hamiltonian (e.g. type of functional etc) and of course the dispersion correction.

References

  1. J.E. Anderson, and P.A. Kirsch, "Structural equilibria determined by attractive steric interactions. 1,6-Dialkylcyclooctatetraenes and their bond-shift and ring inversion investigated by dynamic NMR spectroscopy and molecular mechanics calculations", Journal of the Chemical Society, Perkin Transactions 2, pp. 1951, 1992. https://doi.org/10.1039/p29920001951
  2. S. Grimme, S. Ehrlich, and L. Goerigk, "Effect of the damping function in dispersion corrected density functional theory", Journal of Computational Chemistry, vol. 32, pp. 1456-1465, 2011. https://doi.org/10.1002/jcc.21759
  3. H.S. Rzepa, "C 16 H 24", 2016. https://doi.org/10.14469/ch/191875
  4. H.S. Rzepa, "C 16 H 24", 2016. https://doi.org/10.14469/ch/191876
  5. H.S. Rzepa, "C 16 H 24", 2016. https://doi.org/10.14469/ch/191874
  6. H.S. Rzepa, and H.S. Rzepa, "C 16 H 24", 2016. https://doi.org/10.14469/ch/191880

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The mechanism of diazo coupling: more hidden mechanistic intermediates.

Saturday, March 8th, 2014

The diazo-coupling reaction dates back to the 1850s (and a close association with Imperial College via the first professor of chemistry there, August von Hofmann) and its mechanism was much studied in the heyday of physical organic chemistry.[1] Nick Greeves, purveyor of the excellent ChemTube3D site, contacted me about the transition state (I have commented previously on this aspect of aromatic electrophilic substitution). ChemTube3D recruits undergraduates to add new entries; Blue Jenkins is one such adding a section on dyes.

diazonium

The mechanism can be rate limiting either in the initial electrophilic attack (black arrows) or in the subsequent proton removal (red arrows using an intermolecular base such as chloride anion).[2]. The product is normally assumed to be the trans-diazo compound rather than cis. This distribution is certainly true in the crystal structure database (below, although some examples of cis are known, including azobenzene itself). Would this distribution be reflected in the transition states? Initial attempts by the ChemTube3D team had resulted only in a cis-transition state being located, and they asked me to check this out.

diazo

ωB97XD/6-311G(d,p)/SCRF=water calculations using phenyl diazonium chloride (I do like my counter-ions) coupling to benzene resulted in location of both cis[3] and trans[4] transition states, the former being the lower by 1.0 kcal/mol in free energy (this might well be due to the dispersion stabilisation from π-π stacking). The IRC for the cis is shown below.[5]

cis-diazocis-diazoEcis-diazoG

You can see that the entire process is concerted. The Wheland intermediate normally invoked as part of the mechanism of aromatic electrophilic substitution is not a proper intermediate but a hidden one for the reaction with X=Y=H. The reaction coordinate has a flat top, and that passage along this part represents the hidden Wheland. The reaction barrier is high however, and it is certainly observed that only activated arenes (phenols, anilines, X,Y=OH, NH2) actually couple with diazonium cations. For these, the hidden intermediate is stabilized by the substituent, and no doubt emerges as a real intermediate.

For my thesis work, I studied[2] diazo-coupling of indoles. I might have a go at returning to that work, to see if calculations can replicate my finding, that for unhindered indoles proton removal from the Wheland intermediate is fast, but add a few t-butyl hindering groups and it becomes slow.

PS. Here is the IRC for the formation of trans-diazobenzene.[6]

trans

Such diazo compounds make up a significant proportion of the 50 or so real molecules I have personally added to the collection of 84 million or so thus far identified.

Working with ions has one statistical problem that covalent systems do not have; where to geometrically place the counter-ion. One should really stochastically explore reasonable locations before concluding the likely location of the globally lowest energy pose.

References

  1. S.B. Hanna, C. Jermini, H. Loewenschuss, and H. Zollinger, "Indices of transition state symmetry in proton-transfer reactions. Kinetic isotope effects and Bronested's .beta. in base-catalyzed diazo-coupling reactions", Journal of the American Chemical Society, vol. 96, pp. 7222-7228, 1974. https://doi.org/10.1021/ja00830a009
  2. B.C. Challis, and H.S. Rzepa, "The mechanism of diazo-coupling to indoles and the effect of steric hindrance on the rate-limiting step", Journal of the Chemical Society, Perkin Transactions 2, pp. 1209, 1975. https://doi.org/10.1039/p29750001209
  3. H.S. Rzepa, "Gaussian Job Archive for C12H11ClN2", 2014. https://doi.org/10.6084/m9.figshare.956138
  4. H.S. Rzepa, "Gaussian Job Archive for C12H11ClN2", 2014. https://doi.org/10.6084/m9.figshare.956139
  5. H.S. Rzepa, "Gaussian Job Archive for C12H11ClN2", 2014. https://doi.org/10.6084/m9.figshare.956209
  6. H.S. Rzepa, "Gaussian Job Archive for C12H11ClN2", 2014. https://doi.org/10.6084/m9.figshare.956213

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