Chapter 13 - Spectroscopy Chapter 13 - Spectroscopy YSU 400 MHz N uclear M agnetic R esonance Spectrometer(s)
Jan 02, 2016
Chapter 13 - SpectroscopyChapter 13 - Spectroscopy
YSU 400 MHz Nuclear Magnetic Resonance Spectrometer(s)
Techniques used to find structures of organic moleculesTechniques used to find structures of organic molecules
NMR spectroscopy: Based on the response of magnetic nuclei to an external magnetic field and an energy source (Radio frequency)
IR spectroscopy: Response of bonds within organic molecules to externally applied Infra Red light
UV/Vis spectroscopy: Response of electrons within bonds to externally applied UV or Visible light
Mass spectrometry: Response of molecules to being bombarded with high energy particles such as electrons
13.1 The Electromagnetic spectrum13.1 The Electromagnetic spectrum Figure 13.1
13.2 Two (quantized) energy states 13.2 Two (quantized) energy states Figure 13.2
13.2 Physics Concepts13.2 Physics Concepts
E = h i.e. Energy of the radiation is directly proportional to its frequency ( = Planck’s constant)
= c/i.e. Frequency of the radiation is inversely proportional to its wavelength (c = speed of light)
E = hc/ i.e. Energy of the radiation is inversely proportional to its wavelength
Take home : Longer wavelength, lower energy
Higher frequency, higher energy
Nuclear spins of protons (1H nucleus) Figure 13.3
13.3 Introduction to 13.3 Introduction to 11H NMR – Nuclear SpinH NMR – Nuclear Spin
Energy difference between states increases with field strength Energy difference between states increases with field strength (Fig. (Fig. 13.4)13.4)
Schematic diagram of a Schematic diagram of a nnuclear uclear mmagnetic agnetic rresonance spectrometeresonance spectrometer
Basic operation of a Fourier Transform (FT) NMR Instrument (Basic operation of a Fourier Transform (FT) NMR Instrument (Fig. 13.5)Fig. 13.5)
downfield upfield
upfielddownfield
13.4 NMR Spectrum Characteristics – 13.4 NMR Spectrum Characteristics – Chemical ShiftChemical Shift
Position of signal is the chemical shift
Chemical shift () = position of signal – position of TMS peak x 106
spectrometer frequency
Enables us to use same scale for different size spectrometers (60 MHz, 400 MHz, 850 MHz, etc.)
TMS = (CH3)4Si, signal appears at 0 Hz on spectrum, therefore used as reference
Chemical shifts are reported as ppm (parts per million) relative to TMS and usually occur in the 0-12 ppm range for 1H spectra
13.4 NMR Spectrum Characteristics – 13.4 NMR Spectrum Characteristics – Chemical ShiftChemical Shift
13.5 Effect of molecular structure on 13.5 Effect of molecular structure on 11H Chemical ShiftH Chemical Shift
CH3F CH3OCH3 (CH3)3N CH3CH3
4.3 3.2 2.2 0.9
i.e. electronegativity of other atoms plays a role in shift
CH3CH3
012PPM
~0.9 ppm
N
CH3
H3C CH3
012PPM
~2.2 ppm
H3CO
CH3
0123PPM
~3.2 ppm
CH3F
~4.3 ppm
H
H
H
H
H
HH H
HHCH3CH3
7.3 5.3 0.9Pi electrons reinforce external field and signals show downfield
13.5 Effect of structure on 13.5 Effect of structure on 11H Chemical ShiftH Chemical Shift
CH3CH3
012PPM
~0.9 ppm “R3C-H – alkyl”
012345PPM
H
H H
H ~5.3 ppm “C=C-H alkene”
01234567PPM
H
H
H
H
H
H
~7.3 ppm “Ar-H benzene”
01234567PPM
H3CCH3
CH3
O
CH3NH3C
CH3
13.5 Effect of structure on 13.5 Effect of structure on 11H Chemical ShiftH Chemical Shift
Spectra typically have multiple signals the number depending on the number of unique types of protons
012PPM
13.5 Typical 13.5 Typical 11H NMR SpectraH NMR Spectra
Simple alkane protons – R2CH2
From spectroscopy sheet – chemical shift ~ 0.9-1.8 ppm
0123PPM
H3CO
CH3
Ether protons -O-C-H
From spectroscopy sheet – chemical shift ~ 3.3-3.7 ppm
13.5 Typical 13.5 Typical 11H NMR SpectraH NMR Spectra
13.5 Typical 13.5 Typical 11H NMR SpectraH NMR Spectra
012345PPM
H3CO
CH2
OCH3
Two types of ether protons -O-C-HFrom spectroscopy sheet – chemical shift ~ 3.3-3.7 ppm
CH2 further downfield (two neighbouring O atoms)
0246810PPM
13.5 Typical 13.5 Typical 11H NMR SpectraH NMR Spectra
Aldehyde proton -CHOFrom spectroscopy sheet – chemical shift ~ 9-10 ppm3 types of Ar-H proton – chemical shift ~ 6.5-8.5 ppm
H
O
0246810PPM
13.5 Typical 13.5 Typical 11H NMR SpectraH NMR Spectra
OH
O
Carboxylic acid proton -CO2HFrom spectroscopy sheet – chemical shift ~ 10-13 ppm3 types of Ar-H proton – chemical shift ~ 6.5-8.5 ppm
13.6 Integration – Ratio of different types of H13.6 Integration – Ratio of different types of H
0246810PPM
15 OH
O
Lines on spectra are curves
Areas underneath each curve give a reliable ratio of the different numbers of each type of proton
0123PPM
CH3CH2OCH3
23
3
13.6 Integration – Ratio of different types of H13.6 Integration – Ratio of different types of H
Areas are given as a ratio, not an absolute number
01234567PPM
2 22
3
3OCH2CH3
O CH3
13.6 Integration – Ratio of different types of H13.6 Integration – Ratio of different types of H
13.7 Spin-Spin Splitting – Effect of neighbouring H on shape13.7 Spin-Spin Splitting – Effect of neighbouring H on shape
H C C
H
H
H
Cl
Cl
H C C
H
H
H
Br
H
13.7 Spin-Spin Splitting – Effect of neighbouring H on shape13.7 Spin-Spin Splitting – Effect of neighbouring H on shape
H C C
H
H
H
Br
C
H
H
H
13.7 Spin-Spin Splitting – Effect of neighbouring H on shape13.7 Spin-Spin Splitting – Effect of neighbouring H on shape
13.7 Spin-Spin Splitting – Effect of neighbouring H on shape13.7 Spin-Spin Splitting – Effect of neighbouring H on shape
General rule for splitting patterns
For simple cases, multiplicity for H = n + 1
Where n = number of neighbouring protons
i.e 1 neighbour, signal appears as a doublet
2 neighbours, signal appears as a triplet
3 neighbours, signal appears as a quartet
4 neigbours, signal appears as a quintet, etc.
Complex splitting patterns are referred to as multiplets
13.7-13.10 Basis of Splitting Patterns13.7-13.10 Basis of Splitting Patterns
Cl C C
H
Cl
H
Br
Br
Ho
For red H : neighbouring H (blue) has two possible alignments, either with, or against, the external field (Ho). This effects the local magnetic environment around the red H and thus there are two slightly different frequencies (and thus chemical shifts) at which the red H resonates. Same applies to the blue H.
Cl C C
H
Cl
H
Br
H
Ho
Red H will be a triplet
Cl C C
H
Cl
H
Br
H
Ho
Blue H’s will be a doublet
13.7-13.10 Basis of Splitting Patterns13.7-13.10 Basis of Splitting Patterns
Cl C C
H
Cl
H
H
H
Ho
Red H will be split into a quartet, blue H’s will be split into a doublet
13.7-13.10 Basis of Splitting Patterns13.7-13.10 Basis of Splitting Patterns
Gaps between lines (in Hz) will be the same for adjacent protons (here ~7.4 Hz). This is the coupling constant.
13.7-13.10 Basis of Splitting Patterns - 13.7-13.10 Basis of Splitting Patterns - Coupling Constants
01234567PPM
O O
HH
HH
H
H H
H H
H
H
HH
H
CH3CH2 but which one?
CH3CH2O
Find J and match signals
Using Coupling Constants
If nonequivalent neighbours have same J value then n+1 applies for signal
0123PPM
Cl
H H
HH
H HH
HH
CH3CH2
CH3CH2
CH3CH2CH2
CH2CH2Cl
Coupling Constants – Nonequivalent Neighbours
13.11 Complex Splitting Patterns13.11 Complex Splitting Patterns
When nonequivalent neighbours have different J values then n+1 does not apply for signal
Generally for alkene protons:J trans > J cis
Figure 13.20
13.11 Complex Splitting Patterns13.11 Complex Splitting Patterns
O
H
AcOAcO
AcO
N3
OAc
H
H
HH H
H
13.12 13.12 11H NMR Spectra of AlcoholsH NMR Spectra of Alcohols
Acidic protons exchange with any H2O in sample
Figure 13.21
Glycosyl amide structure from NMR - NOESYGlycosyl amide structure from NMR - NOESY
N-H
N-H
ON
HH
H
H H
O
H
YSUYSU
Glycosyl amide structure from 2-D NMR - COSYGlycosyl amide structure from 2-D NMR - COSY
YSUYSU
H-5H-4H-3
H-2
N-H
H1, H2, H3, and H4 hard to distinguish just from coupling constants (all t, J~9 Hz)
David TemelkoffDavid Temelkoff
ON
H1H5
H3
H4 H2
O
H
13.14 13.14 1313C NMR Spectroscopy C NMR Spectroscopy
Figure 13.23
• Carbon 13 isotope and not 12C is observed in NMR
• 13C very low abundance (<1%), integration not useful
• Spectra usually “decoupled” and signals are singlets
• Number of distinct signals indicates distinct carbons
• Same ideas about shielding/deshielding apply
• Spectra often measured in CDCl3 and referenced to
either the C in TMS (0 ppm) or the C in CDCl3, which shows
as a triplet at 77.0 ppm
13.14 13.14 1313C NMR SpectroscopyC NMR Spectroscopy
13C NMR (ppm) 21, 52, 121, 122, 120, 126, 132, 134, 148, 168, 169
020406080100120140160180PPM
O
O
O
CH3
O
13.15 13.15 1313C NMR Chemical Shifts (see Sheet)C NMR Chemical Shifts (see Sheet)
13C NMR (ppm) 23, 28, 32, 128, 151, 197
020406080100120140160180200PPM
H3C
O
CH3
CH3
H
H
13.15 13.15 1313C NMR Chemical Shifts (see Sheet)C NMR Chemical Shifts (see Sheet)
020406080100120140160180200
PPM
0123456PPM
H3C
O
CH3
CH3
H
H
13.15 13.15 1313C NMR Chemical Shifts (see Sheet)C NMR Chemical Shifts (see Sheet)
020406080100120140160180200PPM
O
13.15 13.15 1313C NMR – Information on SymmetryC NMR – Information on Symmetry
020406080100120140160180200PPM
O
Not covering 13.17-13.19
Information on the types of bonds within moleculesH3C CH3
OH
13.20 Infrared Spectroscopy13.20 Infrared Spectroscopy
13.20 Infrared Spectrometer13.20 Infrared Spectrometer
13.20 Stretching and bending vibrations of a methylene unit13.20 Stretching and bending vibrations of a methylene unit
Figure 13.25
13.20 Stretching and bending vibrations from Spec Sheet13.20 Stretching and bending vibrations from Spec Sheet
Don’t memorize, learn to use as you practice problems
13.20 Interpreting IR Spectra – 13.20 Interpreting IR Spectra – nn-Hexane-Hexane
Figure 13.31
CH3CH2CH2CH2CH2CH3
13.20 Interpreting IR Spectra – 1-Hexene13.20 Interpreting IR Spectra – 1-Hexene
H2C=CHCH2CH2CH2CH3
Figure 13.32
13.20 Interpreting IR Spectra – 13.20 Interpreting IR Spectra – tt-Butylbenzene-Butylbenzene
Figure 13.33
C
CH3
CH3
CH3
13.20 Interpreting IR Spectra – 2-Hexanol13.20 Interpreting IR Spectra – 2-Hexanol
Figure 13.34
CH3CHCH2CH2CH2CH3
OH
13.20 Interpreting IR Spectra – 2-Hexanone13.20 Interpreting IR Spectra – 2-Hexanone
Figure 13.35
CH3CCH2CH2CH2CH3
O
13.21 Ultraviolet-Visible (UV-Vis) Spectroscopy13.21 Ultraviolet-Visible (UV-Vis) Spectroscopy
Figure 13.37 Figure 13.38
Useful for identifying chromophores in molecules (benzene rings, conjugated alkene systems) - More useful in Biochemistry
13.22 Mass Spectrometry13.22 Mass Spectrometry
Gives information on molecular mass and structure
13.22 Mass Spectrometry13.22 Mass Spectrometry
Cl
Exam ProblemsExam Problems
Exam ProblemsExam Problems