Posts Tagged ‘expert chemical knowledge’

Molecule of the year? “CrN123”, a molecule with three different types of Cr-N bond.

Friday, December 16th, 2016

Here is a third candidate for the C&EN “molecule of the year” vote. This one was shortlisted because it is the first example of a metal-nitrogen complex exhibiting single, double and triple bonds from different nitrogens to the same metal[1] (XUZLUB has a 3D display available at DOI: 10.5517/CC1JYY6M). Since no calculation of its molecular properties was reported, I annotate some here.

Firstly, the 14N spectra were recorded, and so it is of interest to see if the chemical shifts reported can be replicated using calculation (ωB97XD/Def2-TZVPP/SCRF=thf). The method selected is not in the least “optimised” for this nucleus; it is often the case that various permutations of functional and basis set must be probed for the best combination for any particular nucleus. Another limitation of the calculation is that it has been done without the (rather large) counterion in place; a full model should certainly include this. The shifts below are referenced with respect to the internal N≡N signal reported at 310 ppm. The calculations have DOI: 10.14469/hpc/1980 (N2) and 10.14469/hpc/1983 (CrN123).

Nucleus N-Cr N=Cr N≡Cr
N(obs,thf), ppm 214 560 963
N(calc,thf), ppm 213;223 558 1093

The match is reasonable for three nitrogens; less so for the Cr≡N variety (DOI: 10.14469/hpc/1982) but no doubt could be improved by playing with the method as noted above and probably also correcting for spin-orbit coupling perturbations of the N nucleus by the Cr nucleus. The 14N shifts of quite a number of other intermediates in the synthesis of this molecule are reported and having a method to hand which can be used to check if the structural assignment matches that calculated for it is always useful. 

Next, I have a look at the nature of the Cr-N bonds themselves. The observed lengths are Cr-N: 1.863 (1.862) 1.881 (1.873); Cr=N 1.736 (1.714); Cr≡N 1.556 (1.518)Å. Calculated values in parentheses. To put this into context, I show CSD (Cambridge structure database) searches (search query DOI:10.14469/hpc/1981) for the three types of CrN bond. Firstly the triple bond (65 examples) which reveals the most probable value of ~1.54Å. This matches fairly well with the above values.

Next, Cr=N (50 examples) with a most probable value of 1.65Å. The value reported for CrN123 (1.736Å) is quite a bit longer for this bond. Again a caveat; the searches specified the bond type exactly, and this does then depend very much on how each entry in the CSD was indexed, by humans perceiving the structure and assigning the bond type on the basis of their expert chemical knowledge. It is quite likely that these integer assignments are at best informed estimates and at worst poor guesses. 

Finally, Cr-N (1398 examples) with the most probable value of 2.07Å which is a fair bit longer than the two values for CrN123. There are relatively few examples in the region of 1.87Å, which is where the CrN123 values come.

If one repeats this search, but limiting the N atom to carrying two carbons as well as a bond to Cr (as in NPri2) one gets the surprise of a bimodal (perhaps even trimodal) distribution, with an additional cluster at lengths of 1.82Å, in closer agreement with CrN123. Again I remind of the caveat that “single” bonds are often assigned by human curators on the basis of perceived chemistry. It would nevertheless be interesting to tunnel down to the possible explanation of this bimodal feature.

These comparisons suggest that in CrN123, the three types of bond are not isolated but may be interacting electronically in a complex manner to increase the bond order of the nominal Cr-NR2 “single” bonds (Cr=N(+)R2) whilst decreasing that of the nominal Cr=N “double” bond. 

Try try to quantify the bond properties a bit more, I tried the ELF basin population technique. ELF (electron localization function) is one method of partitioning the electron density in the molecule into well defined regions or basins (which we call bonds). The results (DOI: 10.14469/hpc/1984) came out Cr-N 4.05 and 4.01e, each comprising two basins which is often typical of a bond with significant π character. The integration for a single bond is of course 2.0. The Cr=N bond was 5.07e in two basins and that for the Cr≡N 3.26e (far removed from ~6.0 in a triple bond). The valence shell total is 16.4e. These values could be said to be “challenging”, perhaps hinting that the bonding and electron density distribution in this molecule is not quite what it seems. Certainly worth a more detailed look with other methods of bond partitioning.

Well, with M123 synthesized, are there any prospects of a M1234 complex being discovered? (quadruple bonds to N HAVE been suggested!).

References

  1. E.P. Beaumier, B.S. Billow, A.K. Singh, S.M. Biros, and A.L. Odom, "A complex with nitrogen single, double, and triple bonds to the same chromium atom: synthesis, structure, and reactivity", Chemical Science, vol. 7, pp. 2532-2536, 2016. https://doi.org/10.1039/c5sc04608d

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Posted in crystal_structure_mining, Interesting chemistry | 10 Comments »

Molecule of the year? "CrN123", a molecule with three different types of Cr-N bond.

Friday, December 16th, 2016

Here is a third candidate for the C&EN “molecule of the year” vote. This one was shortlisted because it is the first example of a metal-nitrogen complex exhibiting single, double and triple bonds from different nitrogens to the same metal[1] (XUZLUB has a 3D display available at DOI: 10.5517/CC1JYY6M). Since no calculation of its molecular properties was reported, I annotate some here.

Firstly, the 14N spectra were recorded, and so it is of interest to see if the chemical shifts reported can be replicated using calculation (ωB97XD/Def2-TZVPP/SCRF=thf). The method selected is not in the least “optimised” for this nucleus; it is often the case that various permutations of functional and basis set must be probed for the best combination for any particular nucleus. Another limitation of the calculation is that it has been done without the (rather large) counterion in place; a full model should certainly include this. The shifts below are referenced with respect to the internal N≡N signal reported at 310 ppm. The calculations have DOI: 10.14469/hpc/1980 (N2) and 10.14469/hpc/1983 (CrN123).

Nucleus N-Cr N=Cr N≡Cr
N(obs,thf), ppm 214 560 963
N(calc,thf), ppm 213;223 558 1093

The match is reasonable for three nitrogens; less so for the Cr≡N variety (DOI: 10.14469/hpc/1982) but no doubt could be improved by playing with the method as noted above and probably also correcting for spin-orbit coupling perturbations of the N nucleus by the Cr nucleus. The 14N shifts of quite a number of other intermediates in the synthesis of this molecule are reported and having a method to hand which can be used to check if the structural assignment matches that calculated for it is always useful. 

Next, I have a look at the nature of the Cr-N bonds themselves. The observed lengths are Cr-N: 1.863 (1.862) 1.881 (1.873); Cr=N 1.736 (1.714); Cr≡N 1.556 (1.518)Å. Calculated values in parentheses. To put this into context, I show CSD (Cambridge structure database) searches (search query DOI:10.14469/hpc/1981) for the three types of CrN bond. Firstly the triple bond (65 examples) which reveals the most probable value of ~1.54Å. This matches fairly well with the above values.

Next, Cr=N (50 examples) with a most probable value of 1.65Å. The value reported for CrN123 (1.736Å) is quite a bit longer for this bond. Again a caveat; the searches specified the bond type exactly, and this does then depend very much on how each entry in the CSD was indexed, by humans perceiving the structure and assigning the bond type on the basis of their expert chemical knowledge. It is quite likely that these integer assignments are at best informed estimates and at worst poor guesses. 

Finally, Cr-N (1398 examples) with the most probable value of 2.07Å which is a fair bit longer than the two values for CrN123. There are relatively few examples in the region of 1.87Å, which is where the CrN123 values come.

If one repeats this search, but limiting the N atom to carrying two carbons as well as a bond to Cr (as in NPri2) one gets the surprise of a bimodal (perhaps even trimodal) distribution, with an additional cluster at lengths of 1.82Å, in closer agreement with CrN123. Again I remind of the caveat that “single” bonds are often assigned by human curators on the basis of perceived chemistry. It would nevertheless be interesting to tunnel down to the possible explanation of this bimodal feature.

These comparisons suggest that in CrN123, the three types of bond are not isolated but may be interacting electronically in a complex manner to increase the bond order of the nominal Cr-NR2 “single” bonds (Cr=N(+)R2) whilst decreasing that of the nominal Cr=N “double” bond. 

Try try to quantify the bond properties a bit more, I tried the ELF basin population technique. ELF (electron localization function) is one method of partitioning the electron density in the molecule into well defined regions or basins (which we call bonds). The results (DOI: 10.14469/hpc/1984) came out Cr-N 4.05 and 4.01e, each comprising two basins which is often typical of a bond with significant π character. The integration for a single bond is of course 2.0. The Cr=N bond was 5.07e in two basins and that for the Cr≡N 3.26e (far removed from ~6.0 in a triple bond). The valence shell total is 16.4e. These values could be said to be “challenging”, perhaps hinting that the bonding and electron density distribution in this molecule is not quite what it seems. Certainly worth a more detailed look with other methods of bond partitioning.

Well, with M123 synthesized, are there any prospects of a M1234 complex being discovered? (quadruple bonds to N HAVE been suggested!).

References

  1. E.P. Beaumier, B.S. Billow, A.K. Singh, S.M. Biros, and A.L. Odom, "A complex with nitrogen single, double, and triple bonds to the same chromium atom: synthesis, structure, and reactivity", Chemical Science, vol. 7, pp. 2532-2536, 2016. https://doi.org/10.1039/c5sc04608d

Tags:, , , , ,
Posted in crystal_structure_mining, Interesting chemistry | 10 Comments »