Comparison of multi-standard and TMS-standard calculated NMR shifts for coniferyl alcohol

1. Comparison of multi-standard and TMS-standard calculated NMR shifts for coniferyl alcohol Heath D. Watts, Mohamed N.A. Mohamed, James D. Kubicki 7 April 2011

2. Goal – Build a reasonably accurate model of lignin testable against spectroscopic data www.lbl.gov/Publications/YOS/Feb/

3. Experimental 13-C NMR data for coniferyl alcohol in acetone Monomer provides less convoluted spectrum, but has ambiguous shifts g b a 1 2 6 Me 3 5 4 http://ars.usda.gov/Services/docs.htm?docid=10491

4. Can computational chemistry methods reproduce the observed NMR chemical shifts for coniferyl alcohol?

5. Energy minimization method: Structure B3LYP/6-311++G(d,p) Cheesemanet al. Journal of Chemical Physics. 1996, 104(14), 5497. NMR Theory: Chemical shielding B3LYP/6-311+G(2d,p); NMR standard: TMS Inorganic character d13C = sTMS - ssample Si

6. 1:1 line MG5 (Watts, 2011) http://ars.usda.gov/Services/docs.htm?docid=10491

7. Is there a conformational isomer effect?

8. g b a 1 6 2 MG1 MG2 MG3 5 3 4 Me MG4 MG5 MG6

9. NMR Theory: mPW1PW91/6-31G(d); NMR standard: benzene  sp2 C; CH3OH sp3 C Organic standards Multi-standard d13C = sM-S – ssample + exp,ref • Sarotti & Pellegrinet; Journal of Organic Chemistry. 2009, 74, 7254. NMR Theory: B3LYP/6-311+G(2d,p); NMR standard: TMS NMR Theory: HF/6-311+G(2d,p); NMR standard: TMS TMS, single standard d13C = sTMS - ssample Cheesemanet al. Journal of Chemical Physics. 1996, 104(14), 5497.

10. MG3 mPW1PW91/6-31G(d) Slope: 1.00 y-intercept (ppm): -0.42 r2=0.994 MUE (ppm): 2.2 RMSE (ppm): 2.4 ppm Max Error (ppm): 3.7

11. NMR Theory: mPW1PW91/6-31G(d); NMR standard: benzene  sp2 C; CH3OH sp3 C NMR Theory: B3LYP/6-311+G(2d,p); NMR standard: TMS NMR Theory: HF/6-311+G(2d,p); NMR standard: TMS

12. Reviewer comments: …the authors conclude that the MG3 should be the “experimentally observable conformer”. In the case of flexible compounds, the generally accepted protocol is to calculate the Boltzmann-averaged shielding constants, which gives a more “realistic” result, because it takes into account the effect of all significantly populated conformations. In addition, the authors did not mention the relative energies of the different conformers.

13. The Gibbs free energy of solution (G°soln) was calculated by: • G°soln = G°IEFPCM + G°TCDG • G°IEFPCM  total free energy in solution with all non-electrostatic terms from the polarized continuum calculation (solvents were acetone, DMSO, & CHCl3) • G°TCDG  thermal correction to Gibbs free energy from the gas-phase frequency calculation • The relative G°soln for each model was determined by setting the model with the lowest G°soln to 0 kJ/mol (Foresman, 1996; www.gaussian.com/g_whitepap/thermo.htm)

15. Boltzmann-weighted NMR chemical shifts to account for contribution of each conformer based the energy distribution (Barone, 2002) • 13CX  Boltzmann averaged chemical shift of atom X • 13CXi  Chemical shift of atom X in conformer i Probability

17. MG3 only mPW1PW91/6-31G(d) Slope: 1.00 y-intercept (ppm): -0.42 r2=0.994 MUE (ppm): 2.2 RMSE (ppm): 2.4 ppm Max Error (ppm): 3.7

18. Conclusion: coniferyl alcohol • For d13C NMR calculations on coniferyl alcohol • Performance of multi-standard method >> TMS-standard method • Linear correlation • Statistical errors • Multiple, Boltzmann-weighted conformers better predict chemical shifts than did comparison of a particular conformer with data

19. Acknowledgments • USDA National Needs Graduate Fellowship Competitive Grant 2007-38420-17782 from the National Institute of Food and Agriculture to H.D. Watts through Nicole Brown. • Instrumentation funded by the National Science Foundation through grant OCI-0821527. • JDK, MNAM, and HDW acknowledge support of the U.S. Department of Energy grant for the Energy Frontier Research Center in Lignocellulose Structure and Formation (CLSF) from the Office of Science, Office of Basic Energy Sciences under Award Number DE-SC0001090. • HDW acknowledges support from Shell Geosciences Energy Research Facilities Award • MNAM was supported by the USDA grant “Improved Sustainable Cellulosic Materials Assembled Using Engineered Molecular Linkers” through Jeff Catchmark. • Computational support was provided by the Research Computing & Cyberinfrastucture group at the Pennsylvania State University. • Discussions with Ming Tien, Brett Diehl, Nicole Brown and other members of the Center for Nanocellulosics and CLSF are also acknowledged.

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