Bulletin of the Korean Chemical Society

Korean Chemical Society (대한화학회)
권호 표지
DOI QR코드

DOI QR Code

NMR Chemical Shift for a 4d$^1$ system when the Threefold Axis is Chosen to be the Axis of Quantization

  • Ahn, Sang-Woon (Department of Chemistry, Jeonbug National University) ;
  • Yuk, Geun-Young (Department of Chemistry, Jeonbug National University) ;
  • Ro, Seung-Woo (Department of Chemistry Engineering, Chungju National Technical College)
  • Published : 1986.04.20
Download PDF
⟨ Previous Next ⟩

Abstract

The NMR chemical shift arising from 4d electron angular momentum and 4d electron spin dipolar-nuclear spin angular momentum interaction for a $4d^1$ system in a strong crystal field of octahedral symmetry, when the threefold axis is chosen as the quantization axis, has been investigated. A general expression using a nonmultipole expansion method is derived for the NMR chemical shift. From this expression all the multipolar terms are determined. We find that the nonmultipolar results for the NMR chemical shift ${\Delta}B$, is exactly in agreement with the multipolar results when $R {\ge} 0.20$ nm. It is also found that the 1/$R^7$ term contributes to the NMR chemical shift almost the same as the 1/$R^5$ in magnitude. The temperature dependence analysis of ${\Delta}B$/B(ppm) at various values of R shows that the 1/$T^2$ term has the dominant contribution to the NMR chemical shift but the contributions of other two terms are certainly significant for a $4d^1$ system in a strong crystal field of octahedral symmetry when the threefold axis is chosen to be the axis of quantization.

Keywords

References

  1. J. Chem. Phys. v.28 H.M. McConnel;D.B. chesnut
  2. Adv. Magnetic Resonan v.1 D.R. Eaton;W.D. Philips
  3. Progr. Nucl. Magnetic Reson. Spectroscopy v.2 E. De Boer;H. Van Wiligen
  4. Physical Chemistry v.4 R.M. Golding
  5. J. Chain. Phys. v.53 B.R. McGarvey
  6. Molecular Phys. v.24 A.D. Buckingham;P.J. Stiles
  7. Mol. Phys. v.31 R.M. Golding;R.O. Pascual;L.C. Stubbs
  8. Mol. Phys. v.31 R.M. Golding;R.O. Pascual;J. Vabancich
  9. J. Magn. Reson. v.2 R.J. Kurland;B.R. McGarvey
  10. J. Magn. Reson. v.33 R.M. Golding;L.C. Stubbs
  11. Advances in Solution Chemistry R.M. Golding;R.O. Pascual;C. Suvanpraporn
  12. J. Magn. Reson. v.46 R.M. Golding;R.O. Pascual;S. Ahn
  13. J. Magn. Reson. v.50 L.C. Stubbs;B.R. McGarvey
  14. Mol. Phys. v.27 P.J. Stiles
  15. Mol. Phys. v.29 P.J. Stiles
  16. Bull. Korean Chem. Sec. v.4 S. Ahn;Sewoung Oh;Euisuh Park
  17. Bull. Korean Chem. Sec. v.6 S. Ahn;Sewoung Oh;Jae Hyun Yang
  18. J. Magn. Reson. v.58 R.M. Golding;R.O. Pascual;I.C. House
  19. Introduction to Ligand Field B.N.Figgis
  20. Introduction to Ligand Field Theory C.J. Ballhausen
  21. Bull. Korean Chem. Soc. v.4 S. Ahn;H.C. Suh;K.H. Lee
  22. Bull. Korean Chem. Soc. v.4 S. Ahn;Euisuh Park;K.H. Lee
  23. J. Chem. Phys. v.38 E. Clementi;D.L. Raimondi
  24. J. Chem. Phys. v.47 E. Clementi;D.L. Raimondi;W.P. Reinhardt
  25. Mol. Phys. v.31 R.M. Golding;R.O. Pascul;L.C. Stubbs