chapter 13 spectroscopy
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Chapter 13 Spectroscopy. Infrared spectroscopy Ultraviolet-Visible spectroscopy Nuclear magnetic resonance spectroscopy Mass Spectrometry. 13.1 Principles of Molecular Spectroscopy: Electromagnetic Radiation. Electromagnetic Radiation. is propagated at the speed of light - PowerPoint PPT PresentationTRANSCRIPT
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Chapter 13Chapter 13SpectroscopySpectroscopy
Infrared spectroscopyInfrared spectroscopy
Ultraviolet-Visible spectroscopyUltraviolet-Visible spectroscopy
Nuclear magnetic resonance spectroscopyNuclear magnetic resonance spectroscopy
Mass SpectrometryMass Spectrometry
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13.113.1
Principles of Molecular Principles of Molecular
Spectroscopy:Spectroscopy:
Electromagnetic RadiationElectromagnetic Radiation
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is propagated at the speed of lightis propagated at the speed of light
has properties of particles and waveshas properties of particles and waves
the energy of a photon is proportional the energy of a photon is proportional to its frequencyto its frequency
Electromagnetic RadiationElectromagnetic Radiation
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Figure 13.1: The Electromagnetic SpectrumFigure 13.1: The Electromagnetic Spectrum
400 nm400 nm 750 nm750 nm
Visible Light
Longer Wavelength (Longer Wavelength ())Shorter Wavelength (Shorter Wavelength ())
Higher Frequency (Higher Frequency ()) Lower Frequency (Lower Frequency ())
Higher Energy (Higher Energy (EE)) Lower Energy (Lower Energy (EE))
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Figure 13.1: The Electromagnetic SpectrumFigure 13.1: The Electromagnetic Spectrum
Longer Wavelength (Longer Wavelength ())Shorter Wavelength (Shorter Wavelength ())
Higher Frequency (Higher Frequency ()) Lower Frequency (Lower Frequency ())
Higher Energy (Higher Energy (EE)) Lower Energy (Lower Energy (EE))
UltravioletUltraviolet InfraredInfrared
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Cosmic raysCosmic rays
RaysRays
X-raysX-rays
Ultraviolet lightUltraviolet light
Visible lightVisible light
Infrared Infrared radiationradiation
MicrowavesMicrowaves
Radio wavesRadio waves
Cosmic raysCosmic rays
RaysRays
X-raysX-rays
Ultraviolet lightUltraviolet light
Visible lightVisible light
Infrared Infrared radiationradiation
MicrowavesMicrowaves
Radio wavesRadio waves
Figure 13.1: The Electromagnetic SpectrumFigure 13.1: The Electromagnetic Spectrum
EnergyEnergy
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13.213.2Principles of Molecular Spectroscopy: Principles of Molecular Spectroscopy:
Quantized Energy StatesQuantized Energy States
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Electromagnetic radiation is absorbed when theElectromagnetic radiation is absorbed when theenergy of photon corresponds to difference in energy of photon corresponds to difference in energy between two states.energy between two states.
E = hE = h
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electronicelectronic
vibrationalvibrational
rotationalrotational
nuclear spinnuclear spin
UV-VisUV-Vis
infraredinfrared
microwavemicrowave
radiofrequencyradiofrequency
What Kind of States?What Kind of States?
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13.313.3Introduction to Introduction to
11H NMR SpectroscopyH NMR Spectroscopy
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11H and H and 1313CC
both have spin = ±1/2both have spin = ±1/2
11H is 99% at natural abundanceH is 99% at natural abundance
1313C is 1.1% at natural abundanceC is 1.1% at natural abundance
The nuclei that are most useful toThe nuclei that are most useful toorganic chemists are:organic chemists are:
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Nuclear SpinNuclear Spin
A spinning charge, such as the nucleus of A spinning charge, such as the nucleus of 11H H or or 1313C, generates a C, generates a magnetic fieldmagnetic field. The . The magnetic field magnetic field generated by a nucleus of spin generated by a nucleus of spin +1/2 is opposite in direction from that +1/2 is opposite in direction from that generated by a nucleus of spin –1/2.generated by a nucleus of spin –1/2.
+ +
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++
+
+
+
The distribution of The distribution of nuclear spins is nuclear spins is random in the random in the absence of an absence of an external magnetic external magnetic field.field.
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++
+
+
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An external magnetic An external magnetic field causes nuclear field causes nuclear magnetic moments to magnetic moments to align parallel and align parallel and antiparallel to applied antiparallel to applied field.field.
HH00
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++
+
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+There is a slight There is a slight excess of nuclear excess of nuclear magnetic moments magnetic moments aligned parallel to aligned parallel to the applied field.the applied field.
HH00
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no difference in absence of magnetic fieldno difference in absence of magnetic fieldproportional to strength of external magnetic field proportional to strength of external magnetic field
Energy Differences Between Nuclear Spin StatesEnergy Differences Between Nuclear Spin States
+
+
EE E E ''
increasing field strengthincreasing field strength
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Some important relationships in NMRSome important relationships in NMR
The frequency of absorbedThe frequency of absorbedelectromagnetic radiationelectromagnetic radiationis proportional tois proportional to
the energy difference betweenthe energy difference betweentwo nuclear spin statestwo nuclear spin stateswhich is proportional towhich is proportional to
the applied magnetic fieldthe applied magnetic field
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Some important relationships in NMRSome important relationships in NMR
The frequency of absorbedThe frequency of absorbedelectromagnetic radiationelectromagnetic radiationis proportional tois proportional to
the energy difference betweenthe energy difference betweentwo nuclear spin statestwo nuclear spin stateswhich is proportional towhich is proportional to
the applied magnetic fieldthe applied magnetic field
UnitsUnits
HzHz
kJ/molkJ/mol(kcal/mol)(kcal/mol)
tesla (T)tesla (T)
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Some important relationships in NMRSome important relationships in NMR
The frequency of absorbed electromagneticThe frequency of absorbed electromagneticradiation is different for different elements, radiation is different for different elements, and for different isotopes of the same element.and for different isotopes of the same element.
For a field strength of 4.7 T:For a field strength of 4.7 T:11H absorbs radiation having a frequencyH absorbs radiation having a frequencyof 200 MHz (200 x 10of 200 MHz (200 x 1066 s s-1-1))1313C absorbs radiation having a frequencyC absorbs radiation having a frequencyof 50.4 MHz (50.4 x 10of 50.4 MHz (50.4 x 1066 s s-1-1))
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Some important relationships in NMRSome important relationships in NMR
The frequency of absorbed electromagneticThe frequency of absorbed electromagneticradiation for a particular nucleus (such as radiation for a particular nucleus (such as 11H)H)depends on its molecular environment. depends on its molecular environment.
This is why NMR is such a useful toolThis is why NMR is such a useful toolfor structure determination.for structure determination.
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13.4Nuclear Shielding
and1H Chemical Shifts
What do we mean by "shielding?"What do we mean by "shielding?"
What do we mean by "chemical shift?"What do we mean by "chemical shift?"
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ShieldingShielding
An external magnetic field An external magnetic field affects the motion of the affects the motion of the electrons in a molecule, electrons in a molecule, inducing a magnetic field inducing a magnetic field within the molecule.within the molecule. CC HH
HH 00
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ShieldingShielding
An external magnetic field An external magnetic field affects the motion of the affects the motion of the electrons in a molecule, electrons in a molecule, inducing a magnetic field inducing a magnetic field within the molecule.within the molecule.
The direction of the The direction of the induced magnetic field is induced magnetic field is opposite to that of the opposite to that of the applied field.applied field.
CC HH
HH 00
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ShieldingShielding
The induced field shields The induced field shields the nuclei (in this case, C the nuclei (in this case, C and H) from the applied and H) from the applied field.field.
A stronger external field is A stronger external field is needed in order for energy needed in order for energy difference between spin difference between spin states to match energy of states to match energy of rf radiation.rf radiation.
CC HH
HH 00
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Chemical ShiftChemical Shift
Chemical shift is a Chemical shift is a measure of the degree to measure of the degree to which a nucleus in a which a nucleus in a molecule is shielded.molecule is shielded.
Protons in different Protons in different environments are shielded environments are shielded to greater or lesser to greater or lesser degrees; they have degrees; they have different chemical shifts.different chemical shifts.
CC HH
HH 00
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01.02.03.04.05.06.07.08.09.010.0
Chemical shift (Chemical shift (, ppm), ppm)
measured relative to TMSmeasured relative to TMS
UpfieldUpfieldIncreased shieldingIncreased shielding
DownfieldDownfieldDecreased shieldingDecreased shielding
(CH(CH33))44Si (TMS)Si (TMS)
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01.02.03.04.05.06.07.08.09.010.0
Chemical shift (Chemical shift (, ppm), ppm)
7.28 ppm7.28 ppm
HH CC
ClCl
ClCl
ClCl
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13.5Effects of Molecular Structure
on1H Chemical Shifts
protons in different environments experience different degrees of shielding and have
different chemical shifts
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Electronegative substituents decreaseElectronegative substituents decreasethe shielding of methyl groupsthe shielding of methyl groups
CHCH33FF 4.3 ppm 4.3 ppm
CHCH33OOCHCH33 3.2 ppm 3.2 ppm
CHCH33NN(CH(CH33))22 2.2 ppm 2.2 ppm
CHCH33CHCH33 0.9 ppm 0.9 ppm
CHCH33SiSi(CH(CH33))33 0.0 ppm 0.0 ppm
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Electronegative substituents decreaseElectronegative substituents decreasethe shielding of methyl groupsthe shielding of methyl groups
CHCH33FF 4.3 ppm 4.3 ppm least shielded Hleast shielded H
CHCH33OOCHCH33 3.2 ppm 3.2 ppm
CHCH33NN(CH(CH33))22 2.2 ppm 2.2 ppm
CHCH33CHCH33 0.9 ppm 0.9 ppm
CHCH33SiSi(CH(CH33))33 0.0 ppm 0.0 ppm most shielded Hmost shielded H
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Effect is cumulativeEffect is cumulative
CHCHClCl33 7.3 ppm 7.3 ppm
CHCH22ClCl22 5.3 ppm 5.3 ppm
CHCH33ClCl 3.1 ppm 3.1 ppm
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Protons attached to spProtons attached to sp22 hybridized carbon hybridized carbonare less shielded than those attachedare less shielded than those attached
to spto sp33 hybridized carbon hybridized carbon
HH HH
HHHH
HH
HH
CC CC
HHHH
HH HH
CHCH33CHCH33
7.3 ppm7.3 ppm 5.3 ppm5.3 ppm 0.9 ppm0.9 ppm
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Table 13.1 (p 496)Table 13.1 (p 496)
Type of protonType of proton Chemical shift (Chemical shift (),),ppmppm
Type of protonType of proton Chemical shift (Chemical shift (),),ppmppm
CCHH RR 0.9-1.80.9-1.8
1.6-2.61.6-2.6CCHH CCCC
2.1-2.52.1-2.5CCHH CC
OO
2.52.5CCHH CCCC
CCHH ArAr 2.3-2.82.3-2.8
CC CC
HH
4.5-6.54.5-6.5
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Table 13.1 (p 496)Table 13.1 (p 496)
Type of protonType of proton Chemical shift (Chemical shift (),),ppmppm
Type of protonType of proton Chemical shift (Chemical shift (),),ppmppm
6.5-8.56.5-8.5
9-109-10
2.2-2.92.2-2.9
3.1-4.13.1-4.1
CCHH BrBr 2.7-4.12.7-4.1
3.3-3.73.3-3.7
HH ArAr
CC
OO
HH
CCHH NRNR
CCHH ClCl
CCHH OO
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Table 13.1 (p 496)Table 13.1 (p 496)
Type of protonType of proton Chemical shift (Chemical shift (),),ppmppm
1-31-3HH NRNR
0.5-50.5-5HH OROR
6-86-8HH OArOAr
10-1310-13CC
OO
HHOO