5th physical chemistry 6 - aalborg universitethomes.nano.aau.dk/lg/5th_physical chemistry_6.pdf ·...
TRANSCRIPT
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Lecture 6
Molecular interaction.Macromolecules and aggregates
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Lecture plan
1. Interaction of molecules with each other and external field:
• Dipole moment• Polarizability• Dipole-dipole interactions• Hydrogen bonding• Hydrophobic interaction
2. Macromolecules• Measurements on macromolecules:
• Light scattering• Sedimentation• Electrophoresis
• Random coil model of a polymer• DNA as an example of a polymer• Micelles, colloids and SAM
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Electric dipole moment
• Dipole moment of a molecule can be calculated by taking into account the locations and magnitudes of the partial charges on all the atoms
Dipole moment measured in C·m or in debye:
30
29
1 3.33564 10dipole moment of 2 electrons separated by 1Å:4.8D=1.6 10
D Cm
Cm
−
−
= ×
×
2 2 2
x j jj
x y z
q xµ
µ µ µ µ
=
= + +
∑
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Electric dipole moment
0.36 132 0.45 0 0.18 182 ( 0.38 ) ( 62 ) 8.8x e pm e pm e pm e pm e pmµ = − × + × + × + − × − =
0.36 0 0.45 0 0.18 ( 87 ) ( 0.38 ) (107 ) 56
0y
z
e pm e pm e pm e pm e pmµ
µ
= − × + × + × − + − × = −
=
X
Y
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Polarization• The polarization, P, of the sample is the dielectric dipole moment density:
mean electric dipole moment of a the molecules multiplied by the number density
P Nµ=
0µ = Ìn an isotropic fluid sample in the absence of an applied electric field
2
3zE
kTµµ = In an electrical field E applied along z direction
This equation can be obtained using Boltzmann distribution:
( )
( )
0
sin , where: ( ) cos , 0sin
E kT
E kT
e ddp E Ee d
θ
πθ
θ θ θ µ θ θ πθ θ
−
−
= = − ≤ ≤
∫
cosz dpµ µ θ= ∫
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Polarizabilities• An applied electric field can distort a molecule as well as align
its permanent electric dipole moment.The induced dipole moment
* Eµ α= where α – polarizability of the molecule
• Polarizability is usually expressed as polarizability volume:
04ααπε
′ =
that has dimension of volume and similar in magnitude to molecular volumes
• Polarizability volume usually correlates with HOMO-LUMO gap, large polarizability correspondes to small gaps
• At high frequencies polarizability drops: – orientation polarization: it takes 1ps for a molecule in liquid to rotate
by 1 rad in fluid, so it’s lost above 1011 Hz– distortion polarization (due to distortion of nuclear position): lost at
frequencies above the particular bond vibration frequency– electronic polarization (due to distortion of electron distribution), the
only polarization that survives in the visual region.
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Relative permittivities• Coulomb interaction of two charges in media
1 2
04 r
q qVrπε ε
=
relative permettivity of the medium
• Permettivity of a substance is large if its molecules are polar or highly polarizable
12
mr
r
PMρε
ε−
=+
Debye equation
• Molar polarization, Pm is defined as:2
03 3A
mNP
kTµα
ε⎛ ⎞
= +⎜ ⎟⎝ ⎠
• in case of no permanent dipole moment: Clausius-Mossottiequation
0
12 3
r A
r
NM
ε ρ αε ε
−=
+
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Experimental determination of dipole moment and polarizabilitiy
• the sample is placed inside a capacitor and capacitance is measured with the sample and without vs temperature
2
0
12 3 3
r A
r
NM kT
ε ρ µαε ε
⎛ ⎞−= +⎜ ⎟+ ⎝ ⎠
• the slope gives molecular dipole moment and the intercept at 1/T=0 gives polarizability
• at the frequencies of visible light Clausius-Mossotti equation can be used to determine molecular polarizability from refractive index
12
r rn ε=
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Interaction between molecules
• van der Waals interaction: the attractive interaction between closed-shell molecules that depends on distance as 1/r6.
• interaction between charges of polar molecules
• strong repulsive interaction at low distances
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Interaction between dipoles
• interaction of a dipole and a point charge
1 22
04qVr
µπε
= −
• dipole-dipole interaction
1 23
02V
rµ µπε
= −
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Interaction between dipoles
• dipole-dipole interaction21 2
30
( ) ( ) 1 3cos4
fV fr
µ µ θ θ θπε
= = −
in case of free rotation the interaction would be zero, but as the dipoles interact the rotation is not free even in a gas phase!
2 21 2
6 20
23 (4 )
CV Cr kT
µ µπε
= − =⋅
Keesom interaction
attractive interaction
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Interaction between dipoles
• dipole-induced dipole interaction2
16
04CV Cr
µ απε
′= − =
• induced dipole-induced dipole interaction– interaction due to transient dipoles resulting
from fluctuations of electron distribution.– called dispersion attraction or London
interaction
1 21 26
1 2
12
I ICV Cr I I
α α′ ′= − =+
I1, I2 – ionization energies of the two molecules
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Hydrogen bonding
• Hydrogen bonding is an attractive interaction between two species that arises from a link of the form A-H …B where A and B are highly electronegative elements and B possesses a lonely pair of electrons. Typical for N, O and FTypical strength: 20kJ/mol (0.2eV)
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Hydrophobic interaction
• individual non-polar molecules when dissolved in water cause formation of clathrate cage around each molecule. As a result this process causes decrease in the entropy
4 4 4
transfer transfer
transfer
(in CCl ) ( )∆ G=+12kJ/mol, ∆ H=-10kJ/mol, ∆ G=-75kJ/mol at 298K
CH CH aq→
• hydrophobicity of a molecular group R can be quantified using a hydrophobicity constant:
0
log SS
π =where S is the ratio of the molar solubility of the compound R-A in octanol to that in water and S0 is the ratio of the molar solubility of the compound H-A in octanol to that in water.
measurements suggest group additivity:
3 2 3 2 2 3 2 3 3, ( ) ( )0.5 1.0 1.5 2.0
R CH CH CH CH CH CH CHπ==
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Total attractive interaction• If hydrogen bonds are not formed than total attractive
interaction between rotating molecules is sum of dipole-dipole, dipole-induced-dipole and induced-dipole-induced-dipole interactions. Overall:
6
CVr
= −
• Repulsive interaction:– hard sphere approximation:
– Mie potential
– Lennard-Jones potential12 6
0 0
13 70 0
0
4
24 2
r rVr r
r rdVFdr r r r
ε
ε
⎧ ⎫⎪ ⎪⎛ ⎞ ⎛ ⎞= −⎨ ⎬⎜ ⎟ ⎜ ⎟⎝ ⎠ ⎝ ⎠⎪ ⎪⎩ ⎭
⎧ ⎫⎪ ⎪⎛ ⎞ ⎛ ⎞= − = −⎨ ⎬⎜ ⎟ ⎜ ⎟⎝ ⎠ ⎝ ⎠⎪ ⎪⎩ ⎭
n mn m
C CVr r
= −
0V r dV r d= ∞ ≤⎧ ⎫
⎨ ⎬= >⎩ ⎭
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Macromolecules• Macromolecules:
– Natural: DNA, polysaccharides, polypeptides etc– Synthetic: polymers
• Macromolecule is monodispersed if it has single definite molar mass. Otherwise, if it is a mixture of molecules of different length, it is polydispersed
• weight-averaged molar mass:2
1 i ii
w i ii i i
i
N MM m M
m N M= =
∑∑ ∑
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Mean molecular mass of Macromolecules
• Various experimental technique used to measure molar masses will result in different types of mean values:– Osmometry: number-average molar mass 1
n i ii
M N MN
= ∑
– Viscosity: viscosity-average molar mass
– Light-scattering: weight-average molar mass
– Sedimentation: Z-average molar mass
2
2
i ii
zi i
i
N MM
N M=∑∑
2
1 i ii
w i ii i i
i
N MM m M
m N M= =
∑∑ ∑
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Mass spectroscopy of macromolecules
• Mass spectroscopy is one of the most accurate techniques for determination of molar masses
• Challenge with macromolecules:difficult to produce gaseous ions without fragmentation
• Most useful techniques: – Electrospray ionization– MALDI-TOF (matrix-assisted laser desorbtion/ionization)
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MALDI-TOF spectroscopy• MALDI-TOF – matrix-assisted laser
desorption/ionization – time-of-flight spectroscopy
macromolecules embedded in a matrix of organic material and inorganic salts
12
2
2
2
2
2
mv zeEd
mt lzeEd
m teEdz l
=
⎛ ⎞= ⎜ ⎟⎝ ⎠
⎛ ⎞= ⎜ ⎟⎝ ⎠
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Laser-light scattering
• as light shines on a particle it creates an oscillating dipole proportional to polarizability and light intensity
• Elastic light scattering: oscillating dipoles in the particle radiate at the incident frequency
• In perfectly homogeneous media all scattered waves interfere destructively and disappear; in an inhomogeneous media radiation is scattered
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Laser-light scattering• Rayleigh scattering: scattering of
light by the particles much smaller than the wavelength of light
• Properties:– intensity of scattered light proportional to λ-4.
– intensity of scattered light proportional to the molar mass of the particle
– intensity of scattered light depends on the scattering angle θ;
– for a very dilute solution excited by plane-polarized light, the Rayleigh ratio:
2
20 sinI rRIθ φ
= ×
2 2 2,0
4
4 ( ), where r r p
p wA
n V dn dcR KP c M K
Nθ θ
πλ
= =for a polymer:
structure factor, takes into account interference of light scattered from different of the same molecule ( )2 2 2 1
22
1
16 sin1
3g
P
RP
θ
θ
π θλ
≈
≈ −macro
small
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Scattering by non-ideal solutions of polymer
• Large molecules displace and reorganize large quantities of solvant i.e. introduce extra entropy changes
• Large molecules exclude other solute molecules from occupied regions
• Enthalpy contribution as solvent-solvent interaction is different from solvent-macromolecule interaction
1pp
w
KcBc
R P Mθ θ
= +
empirical constant
• Q-temperature – temperature at which B=0, the solution at this temperature behaves nearly ideal
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Dynamic light scattering• Dynamic light scattering: as two molecules moves in the solution the
light scattered from them will change from interfering constructively to destructively and back. For large number of particles it results in intensity fluctuations that depend on diffusion coefficient.
, where frictional coefficient 6kTD f af
π η= =
0.6DD Mβ −=For dilute monodispersed polymer,
consisting of random coils:
The size obtained from DLS assumes spherical object, otherwise corrections should be made:
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Ultracentrifugation• sedimentation: process where heavy
particles settle towards the foot of column, can be greatly accelerated by ultracentrifugation
2 2effm r bmrs
f fω ω
= =
(1 )eff sm bm v mρ= = −
drift speed:
2
6
n
A
n
A
bMsSr fN
bMSa N
ω
π η
= =
=
Sedimentationconstant
if we combine DLS and ultracentrifugation we can find molar mass without assuming a particular shape of a molecule
nSRTMbD
=
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Sedimentation equilibrium • during prolonged centrifugation (several days!) an
equilibrium concentration profile can be reached2 21( ) ( )
2r r m rµ µ ω= −Chemical potential at a point r in the solution
2
, , ,,
0T T
T T c T p T pT c
M rr r
p cr p r c r
µ µ ω
µ µ µ
∂ ∂⎛ ⎞ ⎛ ⎞= − =⎜ ⎟ ⎜ ⎟∂ ∂⎝ ⎠ ⎝ ⎠
⎛ ⎞∂ ∂ ∂ ∂ ∂⎛ ⎞ ⎛ ⎞ ⎛ ⎞ ⎛ ⎞= +⎜ ⎟⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎜ ⎟∂ ∂ ∂ ∂ ∂⎝ ⎠ ⎝ ⎠ ⎝ ⎠ ⎝ ⎠⎝ ⎠
2 2 210 02( ) ( ) ( )p r p r r rρω= + −
mV Mv=
0 lnRT cµ µ= +
22 2 2
2 1 1
2 ln( )w
cRTMr r b cω
=−
at equilibrium:
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Electrophoresis• Charged macromolecules (like DNA) move in response to electric field
zeEsf
=drift speed in electrical field E:
challenge: large molecules might require high voltage applied toreach reasonable drift speed, that leads to heating. Solved by capillary electrophoresis• Common materials: agarose (large pores, good for
large macromolecules like DNA) and polyacrylamide (PAGE)
• Proteins have different charge and shape that affect results of electrophoresis. SDS (sodium dodecyl sulfate) denatures proteins and forms a rod-shaped complex with constant charge: SDS-PAGE
• Isoelectric focusing: in a gradient of pH, the protein will stop moving when isoelectric point is reached.
• 2D-electrophoresis: result of isoelectric focusing is further separated by SDS-PAGE
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Viscosity• presence of macromolecules increases viscosity of
the solution
[ ]0 (1 ...)cη η η= + + [ ] 0
00
limc c
η ηηη→
⎛ ⎞−= ⎜ ⎟
⎝ ⎠
Ostwald viscometer
0 0 0
tt
η ρη ρ
= ×
[ ] avKMη =
• Solution of macromolecules often fits Mark-Kuhn-Houwink-Sakurada equation
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Structure and dynamics
• configuration – structural features of a molecule that can be only changed by breaking chemical bonds
• conformation – spatial arrangement of different parts of a chain
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Structure and dynamics
• levels of structure:– primary: the sequence of
molecular residues– secondary: spatial arrangement of
a chain (coils, helicies etc.). Loss of secondary structure is called denaturation
– tertiary: overall three-dimensional structure of the molecule
– quaternary structure: the manner in which large molecules are formed by aggregation of others, e.g. 4 sub-units of haemoglobin
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Structure and dynamics• Random coils – most likely configuration for
identical units not forming hydrogen bondsSimplest model of random coils: Freely joint chain, zero residues volume
Probablity that ends of a one-dimensional freely jointed chain of N units of length l are distance nl apart:
12
2
12
2 2
12
/ 2
32
2
2
3( ) 42
n N
a r
P eN
af r r e aNl
π
ππ
−
−
⎛ ⎞= ⎜ ⎟⎝ ⎠
⎛ ⎞ ⎛ ⎞= =⎜ ⎟ ⎜ ⎟⎝ ⎠ ⎝ ⎠
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Structure and dynamics• Measures of the geometrical size of a random coil
Contour length: cR Nl=
Root mean square separation (average separation of the ends fo a coil):
12
rmsR N l=
Radius of gyration (radius of a shell with equivalent moment of inertia):
1 12 221,2
,
16g i j
i j
NR R lN⎛ ⎞ ⎛ ⎞= =⎜ ⎟ ⎜ ⎟
⎝ ⎠⎝ ⎠∑
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Conformational entropy and Entropic force
• Random coil is a state with highest entropy, stretching reduces the entropy
{ }1 112 ln (1 ) (1 ) , where /v vS kN v v v n N+ −∆ = − + − =
Change in entropy of random coil due to stretching by nl:
, ,
,
T V T V
T V
dU TdS PdV FdxU ST Fx x
SF Tx
= − +
∂ ∂⎛ ⎞ ⎛ ⎞= +⎜ ⎟ ⎜ ⎟∂ ∂⎝ ⎠ ⎝ ⎠
∂⎛ ⎞= − ⎜ ⎟∂⎝ ⎠ ,
1ln2 1T V
T S kTFl n l
νν
∂ +⎛ ⎞ ⎛ ⎞= − = −⎜ ⎟ ⎜ ⎟∂ −⎝ ⎠ ⎝ ⎠
vkT nkTFl Nl
≈ =Small extension:
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Constrained chain model
• Freely joined chain model can be improved by restricting the bond angles
correction factor for Rrms and Rg:1/ 21 cos
1 cosF θ
θ−⎛ ⎞= ⎜ ⎟+⎝ ⎠
for example for tetrahedral bonds:
0
1/ 21/ 2
109.5 2
(2 )3rms g
F
NR N l R l
θ = ⇒ =
⎛ ⎞= = ⎜ ⎟⎝ ⎠
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Structure and stability of polymers
• Synthetic polymers:– elastomers: can expand and contract easily.
perfect elastomer: internal energy independent on the extension, can be modeled as random coil
– fibre: strong polymer due to interaction between chains, example: Nylon-66
– plastic: situation intermediate between elastomer and fibre
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Phase transitions in synthetic polymers
• melting temperature
• glass transition temperature:at temperatures lower than Tg writhing motion of bonds is frozen
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Nucleic acids: primary structure
• Nucleotide monomers
• Watson-Crick base pairs
DNA only RNA only
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Nucleic acids: secondary structure
• DNA secondary structures: All helical !
Standard for DNA;In solution or high humidity; 0.34 nm/bp, 10-10.5 bp/turn
Low humidity, high salt, ethanol environment
0.26 nm/bp -12 bp/turn (left handed)
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Nucleic acids• Hoogsteen pairing: triplex DNA
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Nucleic acids• Hoogsteen pairing: quadruplex G4 (found at the telomere ends)
K+ or Na+
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Nucleic acids• Hoogsteen pairing: quadruplex G4 (found at the telomere ends)
K+ or Na+
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DNA: tertiary structure
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AFM on DNA
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DNA stretching
ξF=0
2*R0
0<F <2pN
Entropic elasticity
10p<F <500pN
Up to~2*l0
The relaxation of a single, 39 µm–long DNA molecule stained with YOYO-1 iodide imaged at 4.5 second intervals. Perkins TT, Quake SR, Smith DE, Chu S. Science 264, 822-826 (1994)
Flow stretched DNA attached to a PS bit
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Denaturation of proteins and nucleic acids
• Denaturation: loss of the natural conformation, can be achieved by temperature of chemical agents
• Thermal denaturation - melting
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Colloids
• colloids:– sol – dispersion of solid in liquid– aerosol – dispersion of liquid or solid in gas– emulsion – dispersion of liquid in liquid
• colloids are thermodynamically unstable due to large surface energy involved
• factors stabilizing colloids: electric charge, protective layer, surfactants etc.
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Colloids• Electrical double layer
– fairly immobile layer of ions and solvent molecules tightly adhered to the surface: radius of shear. electric potential at this layer relative to the bulk of medium is called z zeta potential.
– outer ionic atmosphere
2/ Ds r
repulsionAaV e
Rζ −= +
2 02DRTrF lbερ
=
• Schulze-Hardy rule: hydrophobic colloids are flocculated more effectively by ions of opposite charge with high charge number
attractiveBVs
= −
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Micelles and membranes
• Surfactant or ions can cluster together forming micelles
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Self-Assembled Monolayers• Alkylthiols monolayers on gold
• Thiophene monolayers on gold
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Problems• 19.2a The radius of gyration of a long chain molecule is found to be 7.3
nm. The chain consists of C–C links. Assume the chain is randomly coiled and estimate the number of links in the chain.
• 19.6a Human haemoglobin has a specific volume of 0.749 × 10–3 m3 kg–1, a sedimentation constant of 4.48 Sv, and a diffusion coefficient of 6.9 × 10–11 m2 s–1. Determine its molar mass from this information.
• 19.12a Calculate the contour length (the length of the extended chain) and the root mean square separation (the end-to-end distance) for polyethylene with a molar mass of 280 kg mol–1.
• 19.2a The radius of gyration of a long chain molecule is found to be 7.3 nm. The chain consists of C–C links. Assume the chain is randomly coiled and estimate the number of links in the chain.
• 19.6a Human haemoglobin has a specific volume of 0.749 × 10–3 m3 kg–1, a sedimentation constant of 4.48 Sv, and a diffusion coefficient of 6.9 × 10–11 m2 s–1. Determine its molar mass from this information.