NMR Spectroscopy
clayqn88
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Jul 09, 2009
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About This Presentation
NMR Spectroscopy
Slide Content
Physical techniques
to study molecular structure
to study molecular structure
Detection
Sample
Radiation
X-ray
n
e-
RF
Sample
Radiation
X-ray
n
e-
RF
Example:
How many protein molecules are there in the solution
sample (volume, 100 ml) at the concentration of 0.1 mM?
About samples of biomolecules
How many protein molecules are there in the solution
sample (volume, 100 ml) at the concentration of 0.1 mM?
About samples of biomolecules
1 mm particles
Brownian motion
Brownian motion
1785: Jan Ingenhousz observed irregular motion of coal dust particles in
alcohol.
1827: Robert Brown watched pollen particles performing irregular motion in
water using a microscope. He repeated his experiments with dust to rule out
that the particles were alive.
1905: Einstein provided the first physical theory to explain Brownian motion.
1908: Jean Perrin did experiments to verify Einstein’s predictions. The
measurements allowed Perrin to give the first estimate of the dimensions of
water molecules. Jean Perrin won the Nobel Prize of Physics in 1926 for this
work.
History of Brownian motion
alcohol.
1827: Robert Brown watched pollen particles performing irregular motion in
water using a microscope. He repeated his experiments with dust to rule out
that the particles were alive.
1905: Einstein provided the first physical theory to explain Brownian motion.
1908: Jean Perrin did experiments to verify Einstein’s predictions. The
measurements allowed Perrin to give the first estimate of the dimensions of
water molecules. Jean Perrin won the Nobel Prize of Physics in 1926 for this
work.
History of Brownian motion
0R that require walk werandomFor
rsunit vecto are where...
321
=
++++=
iN eeqeqeqeqR
( ) )ee(MN
q
e...eeeq
1
R
1
R
sexperiment Mover Average
j
ji
i
2M
1k
2
N321
2
1
2
k
2
ååå
¹==
×+=
ú
û
ù
ê
ë
é
++++==
MMM
m
k
2
x
2
y
2
x
2
2
x
2
x
2
222
q2qqq where
2τ
q
4τ
2q
4τ
q
D where4Dt,q
τ
t
NqR may write We
t
N then t,is time total theand τ timea takesand random is stepeach that assume weIf
=+=======
=
t
Each step in the x and y directions are random,
but otherwise equal, such that q
x
2
=q
y
2
y
x
( ) ( ) ( ) ( )
12
2
12
2
12
2
1
2
2
22
21
2
ee22qee211qee2eeqeqeqR
steps) only two (assume Example
×+=×++=×++=+=1
eq
2
eq
Random walk
rsunit vecto are where...
321
=
++++=
iN eeqeqeqeqR
( ) )ee(MN
q
e...eeeq
1
R
1
R
sexperiment Mover Average
j
ji
i
2M
1k
2
N321
2
1
2
k
2
ååå
¹==
×+=
ú
û
ù
ê
ë
é
++++==
MMM
m
k
2
x
2
y
2
x
2
2
x
2
x
2
222
q2qqq where
2τ
q
4τ
2q
4τ
q
D where4Dt,q
τ
t
NqR may write We
t
N then t,is time total theand τ timea takesand random is stepeach that assume weIf
=+=======
=
t
Each step in the x and y directions are random,
but otherwise equal, such that q
x
2
=q
y
2
y
x
( ) ( ) ( ) ( )
12
2
12
2
12
2
1
2
2
22
21
2
ee22qee211qee2eeqeqeqR
steps) only two (assume Example
×+=×++=×++=+=1
eq
2
eq
Random walk
2τ
q
D where4Dt,RMSDDeviation SquareMean
2
x2
====
t
MSD
y
x
1D: MSD=2Dt
2D: MSD=4Dt try to show this yourself!
3D: MSD=6Dt
Random walk
q
D where4Dt,RMSDDeviation SquareMean
2
x2
====
t
MSD
y
x
1D: MSD=2Dt
2D: MSD=4Dt try to show this yourself!
3D: MSD=6Dt
Random walk
Fick’s law of diffusion
dx
dC
DJ-=
Adolf Fick (1855):
J= flux of particles (number of particles per area and time
incident on a cross-section) [m
-2
s
-1
]
D= diffusion coefficient [m
2
s
-1
]
C=concentration of particles [m
-3
]
(sometimes n is used instead of C to represent concentration )
J
A
dx
dC
DJ-=
Adolf Fick (1855):
J= flux of particles (number of particles per area and time
incident on a cross-section) [m
-2
s
-1
]
D= diffusion coefficient [m
2
s
-1
]
C=concentration of particles [m
-3
]
(sometimes n is used instead of C to represent concentration )
J
A
Random walk is due to thermal fluctuations!
1905) ip,relationsh(Einstein
f
Tk
D
B
=
molecules with watercollision todue force random a is R(t)
particles of radiusr whereparticle spherical afor r6f R(t)fv0ma ==+-== hp
fv
v
R(t)
1905) ip,relationsh(Einstein
f
Tk
D
B
=
molecules with watercollision todue force random a is R(t)
particles of radiusr whereparticle spherical afor r6f R(t)fv0ma ==+-== hp
fv
v
R(t)
10
-5
Gas
10
-9
Liquid
10
-13
Solid
D [m
2
/s]State of matter
Diffusion coefficients in different materials
1905) ip,relationsh(Einstein
f
Tk
D
B
=
-5
Gas
10
-9
Liquid
10
-13
Solid
D [m
2
/s]State of matter
Diffusion coefficients in different materials
1905) ip,relationsh(Einstein
f
Tk
D
B
=
Radiation
X-ray
n
e-
RF
X-ray
n
e-
RF
Photons and Electromagnetic Waves
•Light has a dual nature. It exhibits both wave and
particle characteristics
–Applies to all electromagnetic radiation
•Light has a dual nature. It exhibits both wave and
particle characteristics
–Applies to all electromagnetic radiation
Particle nature of light
•Light consists of tiny packets of energy, called photons
•The photon’s energy is:
E = h f = h c /l
h = 6.626 x 10
-34
J s (Planck’s constant)
•Light consists of tiny packets of energy, called photons
•The photon’s energy is:
E = h f = h c /l
h = 6.626 x 10
-34
J s (Planck’s constant)
Wave Properties of Particles
•In 1924, Louis de Broglie postulated that because
photons have wave and particle characteristics,
perhaps all forms of matter have both properties
•In 1924, Louis de Broglie postulated that because
photons have wave and particle characteristics,
perhaps all forms of matter have both properties
de Broglie Wavelength and Frequency
•The de Broglie wavelength of a particle is
•The frequency of matter waves is
h h
p mv
l= =
ƒ
E
h
=
•The de Broglie wavelength of a particle is
•The frequency of matter waves is
h h
p mv
l= =
ƒ
E
h
=
Dual Nature of Matter
•The de Broglie equations show the dual nature of matter
•Matter concepts
–Energy and momentum
•Wave concepts
–Wavelength and frequency
•The de Broglie equations show the dual nature of matter
•Matter concepts
–Energy and momentum
•Wave concepts
–Wavelength and frequency
X-Rays
•Electromagnetic radiation with short wavelengths
–Wavelengths less than for ultraviolet
–Wavelengths are typically about 0.1 nm
–X-rays have the ability to penetrate most materials
with relative ease
•Discovered and named by Röntgen in 1895
•Electromagnetic radiation with short wavelengths
–Wavelengths less than for ultraviolet
–Wavelengths are typically about 0.1 nm
–X-rays have the ability to penetrate most materials
with relative ease
•Discovered and named by Röntgen in 1895
Production of X-rays
•X-rays are produced when high-speed electrons are
suddenly slowed down
•X-rays are produced when high-speed electrons are
suddenly slowed down
Wavelengths Produced
European synchrotron
Grenoble, France
Production of X-rays in
synchrotron
Grenoble, France
Production of X-rays in
synchrotron
European synchrotron
Electron energy: 6 Gev
Electron energy: 6 Gev
European synchrotron
Bending magnets Undulators
Bending magnets Undulators
A typical beamline
The three largest and most powerful synchrotrons in the world
APS, USA ESRF, Europe-France Spring-8, Japan
APS, USA ESRF, Europe-France Spring-8, Japan
Object
Image
Scattering
Lens
Direct imaging method (optical or electronic)
Analogical synthesis
Image
Scattering
Lens
Direct imaging method (optical or electronic)
Analogical synthesis
Object
Image
Scattering
Data collection
Indirect imaging method (diffraction X-ray, neutrons, e-)
Synthesis by computation (FT)
Image
Scattering
Data collection
Indirect imaging method (diffraction X-ray, neutrons, e-)
Synthesis by computation (FT)
Incident
wave
Scattered
wave
Scattering of a plane monochrome wave
Janin & Delepierre
wave
Scattered
wave
Scattering of a plane monochrome wave
Janin & Delepierre
A molecule represented by electron density
Scattering by an object of finite volume
Scattered
beam
Incident
beam
Janin & Delepierre
Scattered
beam
Incident
beam
Janin & Delepierre
Schematic for X-ray Diffraction
•The diffracted radiation is very
intense in certain directions
–These directions correspond
to constructive interference
from waves reflected from the
layers of the crystal
•The diffracted radiation is very
intense in certain directions
–These directions correspond
to constructive interference
from waves reflected from the
layers of the crystal
Diffraction Grating
•The condition for maxima is
d sin θ
bright
= m λ
•m = 0, 1, 2, …
•The condition for maxima is
d sin θ
bright
= m λ
•m = 0, 1, 2, …
http://en.wikipedia.org/wiki/Image:Photo_51.jpg
Photo 51
X-ray Diffraction of DNA
Photo 51
X-ray Diffraction of DNA
Planes in crystal lattice
Bragg’s Law
•The beam reflected from the lower
surface travels farther than the one
reflected from the upper surface
•Bragg’s Law gives the conditions for
constructive interference
2 d sinθ = mλ; m = 1, 2, 3…
•The beam reflected from the lower
surface travels farther than the one
reflected from the upper surface
•Bragg’s Law gives the conditions for
constructive interference
2 d sinθ = mλ; m = 1, 2, 3…
A protein crystal
X-ray diffraction pattern of a protein crystal
http://en.wikipedia.org/wiki/X-ray_crystallography
http://en.wikipedia.org/wiki/X-ray_crystallography
Electron density of a protein
Scattering and diffraction of neutrons
Institut Laue-Langevin,
Grenoble, France
Institut Laue-Langevin,
Grenoble, France
Electrically Neutral
Microscopically Magnetic
Ångstrom wavelengths
Energies of millielectronvolts
Why use neutrons?
Microscopically Magnetic
Ångstrom wavelengths
Energies of millielectronvolts
Why use neutrons?
The Electron Microscope
•The electron microscope depends on
the wave characteristics of electrons
•Microscopes can only resolve details
that are slightly smaller than the
wavelength of the radiation used to
illuminate the object
•The electrons can be accelerated to
high energies and have small
wavelengths
•The electron microscope depends on
the wave characteristics of electrons
•Microscopes can only resolve details
that are slightly smaller than the
wavelength of the radiation used to
illuminate the object
•The electrons can be accelerated to
high energies and have small
wavelengths
Nuclear Magnetic Resonance (NMR) spectroscopy
http://en.wikipedia.org/wiki/Nuclear_magnetic_resonance
Superconducting magnets 21.5 T
Earth’s magnetic field 5 x 10
-5
T
http://en.wikipedia.org/wiki/Nuclear_magnetic_resonance
Superconducting magnets 21.5 T
Earth’s magnetic field 5 x 10
-5
T
• Nuclei can have integral spins (e.g. I = 1, 2, 3 ....):
2
H,
6
Li,
14
N
fractional spins (e.g. I = 1/2, 3/2, 5/2 ....):
1
H,
15
N
or no spin (I = 0):
12
C,
16
O
• Isotopes of particular interest for biomolecular research are
1
H,
13
C,
15
N and
31
P, which have I = 1/2.
• Spins are associated with magnetic moments by:
Spin and magnetic moment
m = għ I
2
H,
6
Li,
14
N
fractional spins (e.g. I = 1/2, 3/2, 5/2 ....):
1
H,
15
N
or no spin (I = 0):
12
C,
16
O
• Isotopes of particular interest for biomolecular research are
1
H,
13
C,
15
N and
31
P, which have I = 1/2.
• Spins are associated with magnetic moments by:
Spin and magnetic moment
m = għ I
A Spinning Gyroscope
in a Gravity Field
A Spinning Charge
in a Magnetic Field
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr2.htm#pulse
Larmor frequency
w = g B
0
in a Gravity Field
A Spinning Charge
in a Magnetic Field
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr2.htm#pulse
Larmor frequency
w = g B
0
Continuous wave (CW) NMR
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
Chemical shift
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
Chemical shift
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
Chemical shift
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
Chemical shift
d = (f - f
ref
)/f
ref
d = (f - f
ref
)/f
ref
Pulsed Fourier Transform (FT) NMR
RF
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
RF
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
Fourier transform (FT) NMR
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
Fourier transform (FT) NMR
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
http://www.cem.msu.edu/~reusch/VirtualText/Spectrpy/nmr/nmr1.htm
http://www.cryst.bbk.ac.uk/PPS2/projects/schirra/html/2dnmr.htm#noesy
Proton 1D NMR spectrum of a protein
Proton 1D NMR spectrum of a protein
Proton 1D NMR spectrum of a DNA fragment
http://www.bruker-nmr.de/guide/
A 2D NMR spectrum
A 2D NMR spectrum
Nuclear Overhauser Effect Spectroscopy (NOESY)
provides information on proton-proton distances
http://www.cryst.bbk.ac.uk/PPS2/projects/schirra/images/2dnosy_1.gif
NOE ~ 1/r
6
provides information on proton-proton distances
http://www.cryst.bbk.ac.uk/PPS2/projects/schirra/images/2dnosy_1.gif
NOE ~ 1/r
6
• Distances between nuclei
• Angles between bonds
• Motions in solution
Information obtained by NMR
• Angles between bonds
• Motions in solution
Information obtained by NMR
Today’s lesson:
•Molecules in solution; Brownian motion
•X-ray
•Scattering and diffraction
•Neutron scattering
•Electron Microscopy (EM)
•Nuclear Magnetic Resonance (NMR) spectroscopy
•Molecules in solution; Brownian motion
•X-ray
•Scattering and diffraction
•Neutron scattering
•Electron Microscopy (EM)
•Nuclear Magnetic Resonance (NMR) spectroscopy
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