Difference between revisions of "Repulsion  Steric(entropic)"
m (→Polymer Size) 

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*4. Dispersion stabilization can be achieved at higher particle concentrations  *4. Dispersion stabilization can be achieved at higher particle concentrations  
Graft or block copolymers commonly used as steric stabilizers are designed to have two groups of different functionality, A and B. A is chosen to be insoluble in the dispersion medium and has strong affinity for the particle surface while B is selected to be soluble but have little or no affinity for the particle surface. Other steric interactions, which give rise to shortrange repulsion in aqueous dispersions due to bare size of ions present at the particle solution interface at high ion concentrations, have been observed.  Graft or block copolymers commonly used as steric stabilizers are designed to have two groups of different functionality, A and B. A is chosen to be insoluble in the dispersion medium and has strong affinity for the particle surface while B is selected to be soluble but have little or no affinity for the particle surface. Other steric interactions, which give rise to shortrange repulsion in aqueous dispersions due to bare size of ions present at the particle solution interface at high ion concentrations, have been observed.  
+  
+  ===Optimizing Steric Repulsion===  
+  
+  In order to optimize the steric repulsion, we consider the steric potential:  
+  
+  <math>V(h)=2\pi kTR\Gamma ^{2}N_{A}\left( \frac{V_{p}}{V_{s}} \right)(0.5x)\left( 1\frac{h}{2\delta } \right)^{2}+V_{elastic}</math>  
+  
+  
+  Where k is Boltzmann’s constant, T is the absolute temperature, R is the particle radius,  
+  <math>\Gamma </math> is the amount adsorbed, <math>N_{A}</math> is Avogadro’s number, <math>V_{p}</math> is the specific partial volume of the polymer, <math>V</math> is the molar volume of the solvent, x is the FloryHuggins parameter, <math>\delta </math> is the maximum extent of the adsorbed layer and Velastic takes account of the compression of polymer chains on close approach.  
+  
+  From this equation, we can see that:  
+  
+  1. Higher adsorbed amount(<math>\Gamma </math>) will result in more interaction/repulsion  
+  
+  2. Distinct cases emerge for different FloryHuggins chainsolvent interaction parameter x. When x<0.5 (good solvent condition), there is maximum interaction on overlap of the stabilizing layers. Osmotic forces cause solvent to move into the highly concentrated overlap zone, forcing the particles apart. If x=0.5, the steric potential goes to zero and for x>0.5 (poor solvent conditions), the steric potential becomes negative and the chains will attract, enhancing flocculation.  
+  
+  3. The steric interaction starts at h= <math>2\delta </math> as the chains begin to overlap and increases as the square of the distance.  
+  
+  4. The final interaction potential is the superposition of the steric potential and the van der Waals attraction.  
+  
+  
+  The following papers by Evans and Napper are helpful in understanding steric stabilization:  
+  
+  [[Media:Steric_stabilization_I.pdf]]  
+  
+  [[Media:Steric_stabilization_II.pdf]]  
+  
    
[[Thin_"soft"_films_and_colloidal_stability#Topics  Back to Topics.]]  [[Thin_"soft"_films_and_colloidal_stability#Topics  Back to Topics.]] 
Revision as of 08:40, 24 November 2008
Contents
Introduction
"When a sol of gelatin, for instance, is added to a gold sol prepared by the reduction of a gold salt in an alkaline medium, it appears that the gold sol is strongly protected against the flocculating action of electrolytes."
H.R. Kruyt, Colloids: A textbook; H.S. van Klooster*, Translator; John Wiley & Sons: London; 1927; p. 87. (*Who I met in the late 1960's)
It had been known for a long time that electrolytes would flocculate many sols; gold sols were a common example. These were call lyophobic colloids. The colloids insensitive to electrolyte were, in hindsight, polymeric. They were call lyophilic colloids. Kruyt reports here that some combinations of the lyophilic colloids could "protect" the lyophobic colloids from salt addition. This lyophilic colloids were also called "protective" colloids.
We now know this mechanism to be polymer adsorption; and in the present context, examples of steric stabilization.
From the very beginning, the stability of polymerstabilized sols has been understood primarily in terms of the solution solubility behavior of the polymer. Polymercoated sols are stable when the polymer is both adsorbed and soluble; and unstable even when the polymer is adsorbed if it is no longer soluble.
Stability of a thin film or a dispersion requires a repulsive force. In this case a "steric" or "entropic" barrier. 
Simple model of steric stabilization
The dispersion energy for two spheres increases as two spheres near each other by Brownian motion.
<math>\Delta G_{121}=\frac{A_{121}d}{24H}</math> 

For the kinetic energy to remain greater than the attractive energy, the distance must be kept greater than H.  <math>kT>\frac{A_{121}d}{24H}</math> 
If polymer layers of thickness 't' around each particle just touch at this distance, 'H':  <math>kT>\frac{A_{121}d}{48t}</math> 
or  <math>t>\frac{A_{121}}{48kT}d</math> 
For example:  
Polymer thickness for stabilization as a function of particle diameter: 
Polymer Size
A polymer increases the viscosity of the solution in a manner dependent on molecular size.
This polymer size can be calculated from the intrinsic viscosity:  <math>\left[ \eta \right]=\underset{c\to 0}{\mathop{\lim }}\,\frac{1}{c}\left( \frac{\eta _{solution}}{\eta _{solvent}}1 \right)</math> 
<math>\left\langle r^{2} \right\rangle ^{1/2}=\left( \frac{2}{5}\frac{MW}{N_{0}}\left[ \eta \right] \right)^{1/3}</math>  Where MW is molecular weight and N0 is Avogadro’s number. 
Or from c* where c* is the concentration where the viscosity is not linear in concentration.  <math>\left[ \eta \right]=\frac{1}{c*}</math> 
Or from a theory where l is the “Kuhn” length.  <math>R_{g}=\frac{l\sqrt{n}}{\sqrt{6}}</math> 
 What about the viscosity DURING the polymerization process?
As a monomer is converted to polymer in a homogeneous system, the viscosity can increase rapidly. In a high viscous medium, small monomer molecules can still diffuse readily to growing chains. So the rate of propagation remains relatively constant, but large growing chains cannot diffuse easily toward each other, and therefore the rate of termination can decrease considerably. Also the "degree of polymerization" increases. This sudden increase in rate, called the "autoacceleration" or the "Trommsdorff effect", is pronounced when highmolecularweight polymer is formed, since the viscosity of the solution increases in proportion to the molecular weight raised to somewhere between the second and fourth power in many cases. The transition from normal kinetics to autoacceleration can be quite sharp and it can be aggravated by the higher heat generation which can raise the temperature and further increase the rate.
A slightly better model
Take into account the compressibility of the outer reaches of the polymer chain: 
Configurations of adsorbed polymers
Polymers in solution  Phase diagrams
Sterically stabilized dispersions are stable when the polymer is soluble – the one phase regions. The higher temperature is called the "lower critical temperature" and the lower temperature is called the "upper critical solution temperature. (No kidding!)  
141 nm silica particles with grafted polymer. Pictures were taken at 0 C and 60 C. The particles phasetransfer with the change in polymer solubility. The upper liquid is ethylacetate and the lower, water. 
Steric Effects and steric repulsion
Steric Effects
Steric effects arise from the fact that each atom within a molecule occupies a certain amount of space. If atoms are brought too close together, there is an associated cost in energy due to overlapping electron clouds (Pauli or Born repulsion), and this may affect the molecule's preferred shape (conformation) and reactivity.
There are a few types of steric effects:
Steric hindrance or steric resistance occurs when the size of groups within a molecule prevents chemical reactions that are observed in related smaller molecules. Although steric hindrance is sometimes a problem, it can also be a very useful tool, and is often exploited by chemists to change the reactivity pattern of a molecule by stopping unwanted sidereactions (steric protection). Steric hindrance between adjacent groups can also restrict torsional bond angles. However, hyperconjugation has been suggested as an explanation for the preference of the staggered conformation of ethane because the steric hindrance of the small hydrogen atom is far too small.
Steric shielding occurs when a charged group on a molecule is seemingly weakened or spatially shielded by less charged (or oppositely charged) atoms, including counterions in solution (Debye shielding). In some cases, for an atom to interact with sterically shielded atoms, it would have to approach from a vicinity where there is less shielding, thus controlling where and from what direction a molecular interaction can take place.
Steric attraction occurs when molecules have shapes or geometries that are optimized for interaction with one another. In these cases molecules will react with each other most often in specific arrangements.
Chain crossing — A random coil can't change from one conformation to a closely related shape by a small displacement if it would require one polymer chain to pass through another, or through itself.
Steric Repulsion
The origins of steric or electrosteric repulsion lie in both volume restriction and interpenetration effects, although it is unlikely that either effect would occur in isolation to provide a repulsive force. In many industrial processes where the coagulation of colloidal particles would naturally occur, steric repulsion between particles can be induced by the addition of a polymer, to prevent the approach of the particle cores to a separation where their mutual van der Waals attraction would cause flocculation to occur. Complete particle surface coverage by absorbed or anchored polymer at high concentration can produce a steric layer that prevents close approach of the particles. The steric layer also acts as a lubricant to reduce the high frictional forces that occur between particles with large attractive interactions. The timedependent, displaceable and slowforming hydrolyzed inorganic layers which lead to repulsive electrosteric forces between mica surfaces in 0.1M Cr(NO_{3})_{3} electrolyte have been reported.
The magnitude of the repulsion resulting from steric forces is dependent upon the surface rare of the particle that the polymer occupies and whether the polymer is reversibly or irreversibly attached to the particle’s surface.
Adsorbed and nonadsorbing surfactants and polymers are widely used to induce steric stabilization. The principal advantages of steric stabilization over charge stabilization are:
 1. Provision of stability in nonpolar media where weak electrical effects occur
 2. Use of higher levels of electrolyte in aqueous media without causing flocculation
 3. Reduction of electroviscous effects arising from particle charge by the addition of electrolyte without flocculation.
 4. Dispersion stabilization can be achieved at higher particle concentrations
Graft or block copolymers commonly used as steric stabilizers are designed to have two groups of different functionality, A and B. A is chosen to be insoluble in the dispersion medium and has strong affinity for the particle surface while B is selected to be soluble but have little or no affinity for the particle surface. Other steric interactions, which give rise to shortrange repulsion in aqueous dispersions due to bare size of ions present at the particle solution interface at high ion concentrations, have been observed.
Optimizing Steric Repulsion
In order to optimize the steric repulsion, we consider the steric potential:
<math>V(h)=2\pi kTR\Gamma ^{2}N_{A}\left( \frac{V_{p}}{V_{s}} \right)(0.5x)\left( 1\frac{h}{2\delta } \right)^{2}+V_{elastic}</math>
Where k is Boltzmann’s constant, T is the absolute temperature, R is the particle radius,
<math>\Gamma </math> is the amount adsorbed, <math>N_{A}</math> is Avogadro’s number, <math>V_{p}</math> is the specific partial volume of the polymer, <math>V</math> is the molar volume of the solvent, x is the FloryHuggins parameter, <math>\delta </math> is the maximum extent of the adsorbed layer and Velastic takes account of the compression of polymer chains on close approach.
From this equation, we can see that:
1. Higher adsorbed amount(<math>\Gamma </math>) will result in more interaction/repulsion
2. Distinct cases emerge for different FloryHuggins chainsolvent interaction parameter x. When x<0.5 (good solvent condition), there is maximum interaction on overlap of the stabilizing layers. Osmotic forces cause solvent to move into the highly concentrated overlap zone, forcing the particles apart. If x=0.5, the steric potential goes to zero and for x>0.5 (poor solvent conditions), the steric potential becomes negative and the chains will attract, enhancing flocculation.
3. The steric interaction starts at h= <math>2\delta </math> as the chains begin to overlap and increases as the square of the distance.
4. The final interaction potential is the superposition of the steric potential and the van der Waals attraction.
The following papers by Evans and Napper are helpful in understanding steric stabilization:
Media:Steric_stabilization_I.pdf
Media:Steric_stabilization_II.pdf