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Nmr spectroscopy of inorganic compounds
1. NMR SPECTROSCOPY OF INORGANIC
COMPOUNDS
PAPER III – INSTRUMENTAL METHODS OF ANALYSIS - I
- Jaiswal Priyanka
- M.Sc. II (Inorganic)
- Semester IV
- Mithibai College (2015-16)
2. Introduction
Nuclear Magnetic Resonance (NMR) is a spectroscopic technique which is based on the
absorption of elelctromagnetic radiation in the radio frequency region 4 to 900 MHz by
nuclei of the atoms.
NMR is used in quality control and research for determining the content and purity of a
sample as well as its molecular structure.
For e.g. NMR can quantitatively analyse mixtures containing known compounds.
For unknown compounds, NMR can
either be used to match against spectral
libraries or to infer the basic structure
directly.
3. Principles of NMR
The theory behind NMR comes from the spin of
a nucleus and it generates a magnetic field.
Without an external applied magnetic field, the
nuclear spins are random in directions.
But when an external magnetic field (BO) is
present, the nuclei align themselves either with
or against the field of the external magnet.
4. If an external magnetic field is applied, an
energy transfer (∆E) is possible between
ground state to excited state.
When the spin returns to its ground state
level, the absorbed radiofrequency energy is
emitted at the same frequency level.
The emitted radiofrequency signal gives the
NMR spectrum of the concerned nucleus.
5. Nuclear Relaxation
Relaxation is the process by which
the spins in the sample come to
equilibrium with the surroundings.
The rate of relaxation determines
how fast an experiment can be
repeated.
The rate of relaxation is influenced
by the physical properties of the
molecule and the sample.
An understanding of relaxation
processes is important for the proper
measurement and interpretation of
NMR spectra.
6. • An Understanding of Relaxation Processes
There are three important considerations.
1. The very small energy difference between α and β states of a nuclear spin
orientation in a magnetic field results in a very small excess population of
nuclei in the ground vs the excited states. For many nuclei, relaxation is a very
slow process, with half-lives on the order of 0.1 to 100 seconds for a spin ½. It
is thus very easy to saturate an NMR transition (equalize populations of excited
and ground state), with the resultant loss in signal quality, and failure to obtain
correct peak areas.
2. NMR lines are extraordinarily sharp, and close compared to higher energy
spectroscopic methods. When relaxation is very fast, NMR lines are broad, J-
coupling may not be resolved or the signal may even be difficult or impossible
to detect.
3. The success of many multipulse experiments, especially 2D and 3D spectra,
depends crucially on proper consideration of relaxation times.
7. NMR Relaxation
-Spin-Lattice or Longitudinal Relaxation
Relaxation process occurs along z-axis
Transfer of the energy to the lattice or the solvent material
Coupling of the nuclei magnetic field with the magnetic field of the ensemble of the vibrational and
rotational motion of the lattice or the solvent.
Results in a minimal temperature increase in sample.
Relaxation time (T1) → Exponential decay.
Mz = M0 [1- e(-t/T1) ]
8. NMR Relaxation
-Spin-spin or Transverse Relaxation
Relaxation process in the X-Y plane
Exchange of energy between excited nucleus and low energy state nucleus.
Randomization of spins or magnetic moment in X-Y plane
Related to NMR peak line-width
Relaxation time T2
T2 may be equal to T1, or differ by orders of magnitude
No energy change
Mx = My = M0 [1- e(-t/T2]
9. (Sn) Tin NMR
Tin is unique in that it has no less than three NMR active spin ½ nuclei, 115Sn,
117Sn and 119Sn.
They all yield narrow signals over a very wide chemical shift range.
119Sn is very slightly more sensitive than 117Sn, so 119Sn is therefore usually the
preferred nucleus.
115Sn is much less sensitive than either 117Sn or 119Sn.
Tin NMR is mostly used for the study of organotin compounds, but is also
applicable to inorganic tin compounds.
10. Comparison of the NMR spectra of the tin
isotopes 115Sn, 117Sn and 119Sn for SnCl4 (neat)
11. (Sn) Tin NMR
All the tin nuclei couple to other nuclei.
1H, 13C, 19F, 31P, etc couplings have been reported.
One bond couplings to 13C are between 1200 and 1500 Hz.
1H one bond couplings are from 1750 to 3000 Hz, 19F from 130 to 2000
Hz and for 31P they range from 50 to 2400 Hz.
Two bond Sn-H coupling constants are approximately 50 Hz.
Homonuclear 119Sn- 119Sn and heteronuclear 119Sn- 117Sn have been
reported from 200 to 4500 Hz.
Three and four bond couplings have been reported.
12. Chemical shift ranges for tin NMR
Each type of tin compound has its characteristic chemical shift range.
13. (195Pt) Platinum NMR
Platinum (Pt) has one medium sensitivity NMR spin -½ nucleus, 195Pt that
yields narrow signals over a very wide chemical shift range.
Because platinum has such a wide chemical shift range and 195Pt gives
narrow signals, the slightest effect can be resolved as in the spectrum in fig.
2 where replacing 35Cl with 37Cl gives extra signals.
195Platinum NMR is mostly used for studying platinum complexes, their
structure, conformation and dynamics, and platinum binding in biological
systems.
Because platinum is widely used as an industrial catalyst and in medicine,
its chemistry and NMR has been widely studied.
14. Fig. 1. 195Pt-NMR spectrum
of K2PtCl4 in D2O
Fig. 2. Resolution enhanced 195Pt-
NMR spectrum of K2PtCl4 in D2O
showing isotopomers
15. Chemical shift ranges for platinum NMR
Each type of platinum has its representative chemical shift range.
16. (195Pt) Platinum NMR
Platinum shows a wide variety of couplings with other nuclei, 1H, 13C, 15N,
31P, etc.
Two-bond couplings to protons are between 25 and 90 Hz.
One-bond 195Pt-15N couplings are in the region of 160 to 390 Hz.
Couplings to 31P are around 1300 to 4000 Hz for one-bond and 30 Hz for
two-bond.
The one-bond coupling to 77Se is between 80 and 250 Hz.
The platinum coupling to 119Sn is especially large and can be over 33000 Hz.
Homonuclear platinum couplings can also be observed.
17. References
1. Physical Methods in Inorganic Chemistry, R. S. Drago, John-Wiley
Pub.,1975
2. Instrumental Methods of Analysis, H.H. Willard, L.L. Merrit, J.A.
Dean and F.A. Settle, C.B.S. Publishers and Distributors, New Delhi,
1986.
3. NMR Spectroscopy, Basic Principles, Concepts, and Applications in
Chemistry,Günther, Harald, 3rd edition, Wiley Publication.
4. Introduction to Spectroscopy, Donald L. Pavia, Gary M. Lampman,
S. Kriz, 5th edition, Pearson Brook/Cole.