Swelling and Collapse of Single Polymer Molecules and Gels
Single polymer molecules
If polymer chains are not ideal, interactions of non-neighboring monomer units ( the so-called volume interactions ) should be taken into account. If these interactions are repulsive, the coil swells with respect to its ideal dimensions. If monomer units attract each other, contraction leads to the “condensation” of polymer chain upon itself with the formation of a ”dense droplet” conformation, which is called a polymer globule.
Coil-globule transition
Polymer gelsThe gel as a whole is actually one giant three-dimensional molecule.
Advantage of studying gels vs. dilute polymer solutions: possibility of direct visual observation of conformational transitions.
Main disadvantage: very slow equilibration in macroscopic gel. For the sample of 1 cm it takes several days. Equilibration time can be diminished by using smaller size L of the sample, one can show that
Swellingof a gel
Collapseof a gel
Repulsive interactions Attractive interactionsof monomer units of monomer units
2~ L
DNA macromolecules
The size of DNA coil and even globule can be of order of the wavelength of visible light (400-700 nm), therefore conformational changes with DNA can be seen by optical microscope. Normally in such experiments for better contrast DNA chain is doped with fluorescent dyes.
DNA coil and globule as revealed by fluorescent microscopy
Single Polymer Chains with Volume Interactions
Main polymer chain models for the considera-tion of volume interactions:
1. Model of beads on a Gaussian filament
Beads of volume on immaterial filament. The connectivity of beads is given by a condition that the the probability distribution for a vector between neighboring beads isr
2
223
2 23
exp2
3)(
ar
arg
Comment: chain connectivityas in the model of beads can be obtained for any chain by selecting the dividing points separated by
several persistent lengths and by assigning all the mass of each chain segment to the dividing point.
a
The value of a is the average distance between neighboring beads. It is possible to have or3a 3a
The beads interact with the interaction potential .Typical interaction po-tential
)(rU
Note: in principle this potential is renormalized by the presence of the solvent, so its form can be much more complicated.
Van-der-Waalsattraction
repulsion due to self-volume of the beads (excluded volume)
r
U
2. Lattice model
Polymer chain is modeled as a random walk
on a lattice. The random walk cannot visit
each site more than once (the excluded
volume condition); the lattice attractive
energy is assigned to each pair of
neighbor sites visited by two non-
consecutive monomer units of the chain.
Concept of -temperature
It should be noted that for both models:
1. At high values of T, the ratio / kT << 1 and only repulsion matters. The coil should swell with respect to the ideal dimensions; this phenomenon is called the excluded volume effect. In this case the so-called swelling coefficient of the coil, , is larger than unity:
2. At low values of T, the ratio / kT >> 1, and attraction dominates. The coil should shrink and form a condensed globule ( coil-globule transition ).
3. At intermediate values of T, the effect of repulsion and attraction should compensate each other and the coil should adopt ideal-chain ( unperturbed ) size. This happens at the so-called -temperature.
10
2
22
R
R
The free energy of a coil is the sum of energetic and entropic contributions:
As to the energy E, contrary to the case of the ideal coil, for the present case it is not equal to zero.
To write down the expression for E we should recall that the concentration of monomer units inside the polymer coil is very small for long chains. Therefore, we can write the expression for E in terms of the expansion in the powers of n:
Here B, C, … are second, third, … virial coefficients; these coefficients are responsible for binary, ternary, etc. interactions of monomeric units. These coefficients depend only on the interaction potential between the units, e.g.
TSEF
rdkTrUTB 3 ))(exp(1 21)(
)( 2 CnBnNkTE
From the expression for B(T ): at high T ( with the decrease of T the value of B diminishes, until it reaches zero at some temperature
At :
The characteristic dependence of thesecond virial coefficient on temperature
At the -temperature chain adopts the conformation of ideal coil.At repulsion dominates, coil swells due to the excluded volume effect - region of good solvent.At attraction dominates, coil shrinks into globule - region of poor solvent.
TSFB 0
T
T
T
BT
T-Θ , where
1kT
Remarks:
1. The fact of complete compensation of interactions at the -point is a specific polymer property (not valid e.g. for gases) connected with low polymer concentration in the coil.
2. Repulsion for and attraction for is valid for the usual form of the potential . For more complicated forms the situation may be reverse, or it may be many -points (see below).
TT
)(rU
The Excluded Volume Problem
Let us consider the polymer coil far above the -point, in the good solvent region, and let us calculate the swelling of the coil due to the excluded volume.
For the second term we used the expression for the entropy of a polymer coil expanded up to the size R (derived earlier).
Excluded volume repulsion (first term) induces the coil swelling, while entropic elasticity (second term) opposes the swelling. The balance (minimization of F with respect to R) gives the equilibrium coil size.
constNa
kTRR
NNkTB
TSNkTBnTSEF
2
2
3 23
43
The free energy of a coil is
Minimization of F with respect to R :
Therefore,
Also swelling coefficient is
The polymeric coil swells essentially due to the excluded volume. In spite of the low polymer concentration in the coil, the swelling is large because of high susceptibility of long polymer chains.
0
RF
024
2
NakTR
RkTBN
53
51
253
51
2 NaNBaR
11015
1
32
1
N
aaN
R
2
2
334 2
3 Na
kTRR
NNkTBF
Swelling of polymer gels
We will consider the gels synthesized in the presence of a large amount of solvent. For such gels entanglements between the gel chains are not important.
Since each subchain of a gel swells independently in its own subvolume:
1. The swelling degree of each subchain is equal to the swelling degree of the gel as a whole.
2. The swelling degree of each subchain is the same as the swelling degree of an isolated chain in the good solvent.
A swollenpolymer gel
11015
1
3 Na
Superabsorbing properties of polyelectrolyte gels
In real case the value of varies between 1.2 and 2.5 which corresponds to a 15-fold increase of the volume of the gel upon swelling in the maximum, except for the case of polyelectrolyte gels.
Polyelectrolyte gels normally increase their volume in water several hundred times. This property is used for the design of superabsorbing polymer systems.
Schematic picture of a polyelectrolyte gel
counter ions
charges onpolymer chains
The superabsorbing properties of polyelectrolyte gels in water are quite universal: they are observed for any gel, independently of its chemical structure, provided that the gel contains charged monomer units.
Since there are charges on polymer chains, there should also be counter ions, because the overall system should be electrically neutral. For these counter ions it is thermodynamically advantageous to abandon the gel and travel in the whole external volume, because in this way they gain significant entropy of translational motion. However, this is impossible, because this would violate the condition of macroscopic electroneutrality of the gel. The counter ions are therefore forced to be confined within the gel, and they produce a significant osmotic pressure in the gel. This osmotic pressure induces a very essential gel swelling: in this way there is more space for the translation motion of each counter ion.
Coil-Globule Transition
Now let us consider the whole range of temperatures. When the temperature is lowered below the Θ-point, the coil-globule transition(or polymer chain collapse) should take place.
T > ; >1 T < ; <1 good solvent poor solvent
The interest to globular form of macromolecules is induced by molecular biophysics: proteins-enzymes are polymeric globules. Denaturation of proteins is sometimes considered to be analogous to the transition from globule to coil.
To determine the characteristics of the coil-globule transition, let us write , as before, but now the expression for both E and S should be different.
Energy: For dense globules higher virial coefficients may be of importance:
The term Bn gives the attraction at , while the term Cn2 gives repulsion, since normally C 2 > 0 in the region of interest. The higher-order virial coefficients can be neglected in the coil-globule transition region.
Thus, omitting, as usual, all numerical coefficients, we have
TSEF
2CnBnNkTE
T
6
2
3 RCN
RBN
NkTE
Entropy: We must take into account the possibility of chain compression (not only extension).
In case of coil
For the globular state
The subchain of g links with ga2 R2
is practically free ( ~ one encounter with the “wall” loss of entropy per this subchain); .
aNR 21
aNR 21
2
2
2
2
23
NaR
NakR
S
2
2
RNa
kgN
kS
122 aRg
Interpolation formula valid (in the orders
of magnitude) for ,
and in the intermediate region:
Finally we have for the free energy:
Minimization of F with respect to R ( ) gives
aNR 21 aNR 2
1
2
2
2
2
RNa
NaR
kS
2
2
2
2
6
2
3
RNa
NaR
kTR
CNRBN
NkT
TSEF
0 RF
23
32
2
5
BNR
CNRNa
NaR
Or in terms of , ,
we have
xy 35
3
21
3
21
υτ
aN
aBN
x
222 NaR 6
2
6
υaa
Cy
poor solvent - point good solvent
x2
Conclusions:
1 Coil-globule transition takes place at , i.e. , this is only slightly lower the -point. It is enough to have a very weak attraction to induce the transition into globule (this is not the case for condensation of gases). Reason: due to the chain connectivity the independent motion of monomer units is impossible (polymer coil is poor in entropy).
2 For y<<1 the chain collapse is discrete, while for y ~ 1 it is continuous. The value of y depends on /a3 ( y 2/a6 ). For << a3 y << 1, while for a3 y ~ 1. For realistic chain models y << 1 corresponds to stiff chains, and y 1 to flexible chains. Indeed, it can be shown that C d 3 l 3; a l , therefore
y = C / a6 d 3/ l 3. Thus, for stiff polymer chains the collapse is discrete, while for flexible chains it is continuous.
1 1 21332
1 NaaN
1x
3 In the limit of small , B < 0 ( globular region ) the size of the globule is defined by the following two terms:
Thus the size of the globule is
or
The volume fraction of monomer units within the globule is
(a) For the globule (cf. with
for ideal coil and for the coil with excluded volume).
23
3
BNR
CN
BCN
R 3
31
31
NBCR
τ υ
τ υυBυ υ 23
CRNn
31
~ NR2
1~ NR 5
3~ NR
3 (b) In the globule far from -point ( || 1) the volume fraction of monomer units is generally not small. This is a dense liquid droplet.
3 (c) The globule swells as the -point (and the coil-globule transition point) is approached, so the description in terms of B and C only in the vicinity of transition point is valid.
The volume fraction of
Volume fraction of monomer units within the globule as a function of ||
Θ τ
Φ
4 Experimentally the coil-globule transition was observed for many polymer-solvent systems. A very convenient system is polystyrene in cyclohexane, since the
-temperature for this case corresponds to
= 35 oC.Main difficulty for the experimental
observation of the coil-globule transition is connected with the possibility of intermolecular aggregation and formation of precipitate, rather than coil-globule transition. To avoid this the concentration of polymer in the solution should be very small ( e.g. for polystyrene-cyclohexane system it should be less than 10-4 g/l ).
Formation of precipitate in the poor solvent region
5 One of the most interesting possibilities to study the coil-globule transition for the particular case of DNA molecules is to use direct visualization via fluorescence optical microscopy. In this case one may work in the range of much lower polymer concentrations (up to 10-5 g/l) and the problem of chain aggregation is not very serious. One may observe the bimodality of the histogram of observed sizes which is the indication of the first ordered coil-globule transition. This is in full agreement with the theory outlined above, since DNA is a stiff-chain polymer.
Histogram of DNA sizes as a function of concentration of added
poly(ethylene oxide) - agent making solvent quality poorer.
Collapse of polyelectrolyte gels
At some critical solvent composition the several-hundred-fold jumpwise decrease of the gel volume is observed.
The amplitude of the jump is directly connected with the polyelectrolyte nature of the gel: it increases with an increase of the degree of charging of the gel chains.
The gel shows high responsiveness to the external actions in the region of jumpwise collapse. In this region it is enough to change the external conditions ( solvent quality, salt concentration, pH, temperature ) only slightly to obtain a very strong reaction of the system.
The dependence of a volume of a polyelectrolyte gel V on the volume fraction of the poor solvent added to water.
, %
V/V0