Transcript Slide 1

BCHM 313 – Physical Biochemistry
Spectroscopy
Dr. Bruce Hill
Email: [email protected]
Office: Rm. 628 Botterell Hall
Lab: Rm. 633
BCHM 313 – Spectroscopy
Spectroscopy refers to the study of the interaction of electromagnetic
radiation with matter. Spectroscopy is useful in both qualitative (what
does the matter look like) and quantitative analysis (how much).
We are going to consider aspects of,
1) UV-visible absorption
2) Fluorescence
3) Circular dichroism
4) Electron Paramagnetic Resonance (very briefly)
The Electromagnetic spectrum
Wavelength λ (m)
10-13
10-10
10-6
10-2
102
106
γ-rays
x-rays
v=c/λ
UV
Radio
frequencies
Vis
IR
microwaves
Frequency ν (Hz or s-1)
1022
E=hv
10-11
1019
1015
1011
107
103
10-26
10-30
Energy per photon (J)
10-14
10-18
10-22
Useful spectroscopic regions for biomolecules
Typical λ (m) Energy (kJ/mol) Spectroscopic region Application
10-13
109
γ-ray
10-10
106
X-ray
10-7
5 x10-6
10-5-10-4
Mössbauer
Diffraction, scattering
103
Vacuum UV-UV Electronic spectra
C-C bond energy
5 x102
Visible
Electronic spectra
1-10•••RT at 25oC•••IR
Vibrational spectra
10-2
10-2
Microwaves
EPR
1
10-3
Radiowaves
NMR
The nature of electromagnetic radiation
x
E
y
M
z
Wave of electric and magnetic vectors
Photons with discrete energy, E = hν
Speed of propagation (c) is related to frequency (ν) and wavelength (λ)
c = ν λ
(cm/s) (cm) (s-1)
Stuff, what stuff- what is matter?
Properties of matter are dependent on,
1) Energetic state- energy levels are quantized
2) Shape- e.g., bond angle between H and O atoms in H2Ominimal energy
- the well-defined shape of folded protein-energetic minimum
3) Dynamics- molecules in solution have kinetic energy
rotate, translate, vibrate
These properties are interrelated
Energy levels
Ground state- state of lowest energy
Excited state – states of energy higher than ground state
States of equal energy are referred to as degenerate
Energy classes
translation
rotation
vibration
electronic
electron spin orientation
nuclear spin orientation
When electromagnetic radiation and matter meet
1) Scattering
2) Absorption
3) Emission
4) Photochemistry
The absorption process
Excited state
E2
hv
E1
Absorption occurs when there
is a match between the energy
of the impinging radiation and the
gap between the two states
Ground state
E2-E1= ΔE = hν, h= Planck’constant
ν= frequency (s-1)
For there to be net absorption there must be a population
difference between the two states, favouring the ground state
Boltzmann distribution
Governs the distribution of molecules across the available energy
levels
E2
#of molecules in E2 nE2
= n
#of molecules in E1
E1
Excited state
= exp(-ΔE/RT) , for 1 mole
If ΔE<<RT, exp(-ΔE/RT) ~e0→1
ΔE>>RT, nE2<<nE1
E1
Ground state
Boltzmann distribution (cont.)
At T= 300 K,
For ΔE = 11.9 J/mol,
(rotational transition)
nE2
nE1
=0.9952
nE2
nE1
=1.86 x 10-21
For an electronic transition,
ΔE = 119 kJ/mol,
Ultraviolet – Visible absorption spectroscopy
1) Transitions between different electronic energy states
2) Spectral regions 200-400 nm (ultraviolet)
400-750 nm (visible)
3) Chromophore-group giving rise to electronic transition
4) Characterized by position of maximum (λmax)
and the extinction coefficient (ε)
5) Electronic energy levels are described by molecular orbitals,
π, π*, n, and d, charge transfer
6) Timescale- electronic transitions occur in ~ 10-15 s
7) λmax and ε can be used for concentration measurements
and for interactions with other molecules
The Beer-Lambert Law
Relates absorbance to the concentration of a chromophore.
What about scattering ?
Electromagnetic radiation
i.e., light of intensity Io
Some is transmitted, intensity I
%T= I/Io
A= log (1/%T)= log(Io/I) = ε c l
A – absorbance
ε – extinction coefficient (M-1cm-1)
c – concentration (M)
l – pathlength (cm)
For a chromophore with ε of
10,000 M-1cm-1, at a concentration of 1 mM in a pathlength
of 1 cm - A would be 10.
Chromophores of biological interest
ε max(M-1cm-1)
7000
Chromophore
Peptide bond
λmax(nm)
190-200
DNA bases
~ 260
10000
280
274
257
5600
1400
200
260
259
340
18000
14400
6230
443
460
410
1000
1270
120000
Aromatic amino acids
TRP
TYR
PHE
NAD+
NADH
Flavin
FMN
FAD
Heme