Instrumental analysis notes NMR spect. -3Modified PDF

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These notes provide an introduction to NMR spectroscopy, explaining its principles, instrumentation, applications, and calculations including chemical shifts.

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Instrumental analysis notes

CHEMSTRY DEPARTMENT
GRADE FOUR
Prof. Dr. Samy Abuelwafa
Dr. Fouz Omar
Instrumental analysis notes
Lecture 3: NMR Spectroscopy of Chemical Compounds
Lectur 3 contents:
Introduction to NMR Spectroscopy.
The instruments used to analysis based on NMR
spectroscopy.
Application in coordination chemistry and Examples.
Questions
References and Videos.
 Introduction to NMR Spectroscopy
NMR spectroscopy is an effective tool used for examining the electronic structure of
a molecule and properties of various chemical species. It is based on the absorption of
electromagnetic radiation in the radio-frequency (RF) region. The frequencies of NMR
transitions are typically in the range of 10→1000 MHz, and nuclei of atoms are detected by
this radiation.

Concept of Quantum Number
 Nuclear magnetic resonance is suitable for studying compounds containing elements with
magnetic nuclei, especially hydrogen. Nuclear magnetic resonance (NMR) is the most
powerful and widely used spectroscopic method for the determination of molecular
structures in solution and pure liquids.
There are few elements that contain nucleus possessing powerful magnetic properties,
So they can be analyzed by NMR technique such as: 1H, 19F, and 31P. These elements have
odd number of protons or neutrons and their nuclear spin quantum number =1/2. Where,
magnetic quantum number = +½ or – ½.
By applying external magnetic field Βo , the directions of magnetic moments leads to
splitting the energy of spin motion into two energy levels calculated from the equation:
E=-mµΒo /l
E1= –mµΒo / ½ Where: m= + ½ , E= -µΒo
E2= -mµΒo / ½ Where: m= - ½ , E= +µΒo
ΔE = E1 - E2 = +µΒo – (-µΒo) =+µΒo +µΒo =2µΒo

A nucleus of spin I can take up 2I + 1 orientations relative to
the direction of an applied magnetic field.
 Nuclei with spin quantum number of 0 have no angular momentum
and are therefore not observable by NMR ( Examples: 12C, 16O, 32S).
 Almost every atom has an isotope that can be studied by NMR.
 Nuclei with spin > ½ have poor magnetic properties and are not
commonly studied. Examples: 2H, 14N (I=1 integer no.).
 The most commonly studies nuclei, especially for biological samples,
are: 1H, 13C, 15N, 19F, and 31P.
 13C and 15N are stable isotopes, but have low natural abundance ( 13C =
1.1% , 15N = 0.36%)
 NMR uses electromagnetic radiation in the radio frequency range
Long wavelength, very low energy. Low energy has significant
consequences:
Sharp signals (Good)
Poor sensitivity (Bad)
Longer experiment time (Bad)
 The sensitivity of NMR depends on several factors, including
the abundance of the isotope and the size of its nuclear magnetic
moment. For example, 1H, with 99.98 per cent natural abundance
and a large magnetic moment, is easier to observe than 13C, which
has a smaller magnetic moment and only 1.1 per cent natural
abundance. With modern multinuclear NMR techniques it is
particularly easy to observe spectra for 1H, 19 F, and 31 P, and useful
spectra can also be obtained for many other isotopes.
Notice that nuclei with even atomic numbers and even mass
numbers (such as 12C and 16O) have zero spin and are invisible in
NMR spectum.
Nuclear spin characteristics of common nuclei used in NMR
Nuclear spin characteristics of common nuclei used in NMR
1-Chemical shift
 Chemical shifts in NMR (Nuclear Magnetic Resonance) spectroscopy refer to
the phenomenon where the resonant frequency of a nucleus in a magnetic field is
influenced by its chemical environment. This effect arises from the shielding or
deshielding of the nucleus by the surrounding electron cloud.
TMS acts as a standard because it is chemically inert, symmetrical, volatile (bp = 27
C), and soluble in most organic solvents. Most importantly, it gives a single absorption
peak and its protons are more shielded than almost all organic protons. ( more shielded
means more toward the right of the spectrum and a lower chemical shift).
 Tetramethylsilane (TMS) is often used as a reference compound. The Si atom
is electropositive with respect to carbon, therefore the electron density on the
methyl groups is higher than would be found on the equivalent hydrocarbon. The
high electron density shields the methyl carbon and protons, leading to a lower
effective field at the nucleus and a lower resonance frequency.
EXAMPLE:
For CHCl3, there is a peak at 1451 Hz in a H1 NMR spectra from a 400 MHz
spectrometer. Convert to δ (ppm) units.
Solution
δ = ((1451 Hz - 0 Hz)/400,000,000 Hz) x 106 ppm = 3.627 ppm
Remember: TMS is our standard and is set to 0 Hz (or 0 ppm).

The following discussion is about protons, but applies to any NMR active nuclei.
Since all protons have the same magnetic moment it might be expected that all
hydrogen atoms will resonate at the same frequency and only give rise to a single, but
different protons will give rise to slightly (ppm) different frequencies. The reason is
that the effective magnetic field Beff that a nuclei experiences is equal to the very
large static magnetic field (B0) plus a much smaller shielding magnetic field which
arises from electrons surrounding the nucleus.
 A common standard for 1H, 13C, or 29Si spectra is tetramethylsilane Si(CH3) 4 (TMS).
When δ < 0 the nucleus is said to be shielded (with a resonance that is referred to as
occurring at ‘low frequency’) relative to the standard; δ > 0 corresponds to a nucleus
that is deshielded (with a resonance that is said to occur at ‘high frequency’) with
respect to the reference.

An H atom bound to a closed-shell, low-oxidation-state, d-block element from Groups 6
to 10 (such as [HCo(CO)4]) is generally found to be highly shielded where as an oxoacid
(such as H2SO4) is deshielded.

The H chemical shift in CH4 is only 0.1 because the H nuclei are in an environment
similar to that in the standard, tetramethylsilane, but the H chemical shift in GeH4 is δ =
3.1
2-Area Under the Peaks(Integral Line)

However when more than one signal is observed, this
integral line will appear and help determine the structure of
certain groups.
Spin--Spin Splitting
3-The Origin of Spin-Spin Splitting
Different numbers of equivalent adjacent nuclei will cause different splitting
patterns and the pattern follows Pascal’s triangle
Notes:
Notes
Instrumentation
NMR Spectrometer constituents:
1.sample holder
Glass tube with 8.5 cm long, 0.3 cm in diameter.
2.Permanent magnet
It provides a homogeneous magnetic field at 60-100 MHZ
3.Magnetic coils
These coils induce a magnetic field when current flows through them
4.Sweep generator
To produce an equal amount of magnetic field pass through the sample
5.Radio frequency transmitter
A radio transmitter coil transmitter that produces a short powerful pulse of radio
waves
6-Radio frequency receiver
A radio receiver coil that detects radio frequencies emitted as nuclei relax to a
lower energy level
7-Read out systems
A computer that analyses and records the data.
 NMR Spectrometer includes a radio station and recording studio. RF pulses at
specific frequencies are pulsed at high energy into the sample (Radio station) which
sits inside the magnet. Tiny currents are then picked up by the receiver coil,
amplified, and digitized into a signal (Recording studio) and collecting to line
spectrum.
 The coupling of the nuclear spins of different isotopes is called
heteronuclear coupling; the GeH4 coupling just discussed is an example.
Homonuclear coupling between nuclei of the same isotope is detectable when the
nuclei are in chemically inequivalent locations.

A multiplet of 2I + 1 lines is obtained when a nucleus of spin 1/2 (or a set of
symmetry-related I = 1/2 nuclei) is coupled to a nucleus of spin I. In the spectrum of
GeH4 shown in the following Fig., the single central line arises from the four
equivalent H nuclei in GeH4 molecule that contain Ge isotopes with I = 0. This
central line is surrounded by 10 evenly spaced but less intense lines that arise from
a small fraction of GeH4 that contains 73Ge, for which I = 𝟗Τ𝟐; the four 1H nuclei are
coupled to the 73Ge nucleus to yield a 10-line multiplet (2 *9Τ2 +1 = 10).
 The 1H-NMR spectrum of GeH4. The main
resonance is at δ = 3.1 with satellites given by
J(1H- 73Ge) spin–spin oupling
 The 19F NMR spectrum of ClF3 is shown as above, The signal ascribed to the two axial F nuclei (each
with I = 1/2 ) is split into a doublet by the single equatorial 19F nucleus, and the signal from the latter
is split into a triplet by the two axial 19F nuclei (19F is in 100 per cent abundance). Thus, the pattern of
19F resonances readily distinguishes this unsymmetrical structure from trigonal-planar and trigonal

pyramidal structures, both of which would have equivalent F nuclei and hence a single 19F resonance.
 Usually these protons can be exchanged with D2O. To verify that a particular peak is
due to O—H or N—H, shake the sample with D2O to exchange the H for a D. If the
deuterium is invisible in the proton NMR so the original signal for the OH will disappear.

Although most NMR measurements are conducted
on diamagnetic compounds, paramagnetic samples are also
amenable to analysis and give rise to special effects indicated
by a wide chemical shift range and broadened signals.
Paramagnetism diminishes the resolution of an NMR spectrum
to the extent that coupling is rarely resolved.
 The NMR spectra of solids rarely show the high resolution that can be
obtained from solution NMR. This difference is mainly due to anisotropic
interactions such as dipolar magnetic couplings between nuclei, These effects
mean that in the solid state chemically equivalent nuclei might be in different
magnetic environments and so have different resonance frequencies. A typical
result of these additional couplings is to produce very broad resonances, often
more than 10 kHz wide.
The broadening of signals can sometimes be so great that signal widths are
comparable to the chemical shift range for some nuclei. This broadening is a
particular problem for 1H, which typically has a chemical shift range of Δ δ = 10.
Broad signals are less of a problem for nuclei such as 195Pt, for which the range
in chemical shifts is Δ δ = 16 000, although this large range can be reflected in
large anisotropic linewidths.
References:
1. Basics of NMR Spectroscopy, Mark Maciejewski,[email protected], Nov 29, 2016
2. Inorganic chemistry P.W. Atkins, T.L. Overton, J.P. Rourke, M.T. Weller, and F.A. Armstrong, Oxford
University Press,2014
3. Nuclear Magnetic Resonance Spectroscopy, Teresa Lehmann, USA; tlehmann, 2018
4. Paramagnetic Complexes in Solution: The NMR Approach, Köhler, Frank H. "". , John Wiley & Sons, (2011).
5. Physical Methods in Chemistry (2nd ed.), Drago, Russell S., Philadelphia: W. B. Saunders, (1977).
6. file:///C:/Users/it/Desktop/Instrumental%20%20analytical%20chemistry(4th%20grade)/Spectroscopy/NMR%2
0Spectroscopy/nmr_ref_notes_2011.pdf
7. 5.5: Chemical Shift - Chemistry LibreTexts

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