Polymer chemistry Polymer chemistry
Factors Influence on the Molecular Weight Molecular Weight Control in Linear Polycondensation Molecular Weight Distributions in Linear Polycondensation Part 3 Molecular Weight and MWD
Closed system : = + 1 Unclossed system : = The Factors Influence on the Molecular Weight of Polycondensation The Balanced Characteristic
Self-Catalyzed system : = 2k 3 t + 1 External Catalysis system : = k 2 C 0 t + 1 The Catalyzed System
With the same mole ratio of groups : = The Extent of Reaction
Key: Deactivation of the functional end groups, i.e., stabilization of molecular weight Molecular Weight Control in Linear Polycondensation One way is slightly over weight of one reactants (non-stoichiometric). Finally another reactant completely react and all the chain ends posses the same functional group. Another way is to add a spot of monofunctional monomer.
For the systems of a-R-a + b-R ‘ -b, not a-R-b The numbers of A and B functional groups are given by N a and N b, respectively. The stoichiometric imbalance r of the two functional groups is given by r=N a /N b ( r≤1). B-B is present in excess. Case 1 Non-stoichiometric of Functional Groups and if the reaction tends to the end,
a-R-a b-R'-b The number of group A is N a The number of group B is N b The number of a-R-a is given by Na/2 The number of b-R-b is given by N b /2 The total of monomer molecules (namely the total of construction units) is given by ( N a + N b ) / 2 The non-stoichiometric reactants At time of 0,
The total of macromolecules The extent of reaction of group a is given by Pa Reacted a : NaPa b : NaPa Unreacted a : Na(1 - Pa) b : Nb - NaPa The total of unreacted a and b is given by: Na + N b - 2NaPa The total of macromolecules is : (Na + Nb - 2NaPa ) /2 At time of t, Then
Thus Substitute r=Na/Nb The moles of the two groups are equal ( r=1 ) The group A is used up ( Pa=1) If r =1
Theoretically, if the mole ratio of the two functional groups in the systems of a-R-a + b-R ‘ -b can be kept equal , the average degree of the condensation polymer will reach the maximum to the end of reaction.
The Excessive percentage q of b-R ‘ -b molecule is often used besides r. The q is defined as: namely Excessive mole-percent q
R"-b can react with group a in the polymer. By this method, the end groups are captured, giving the stabilized molecular weight. The molecular weight of polymer can be adjusted by R”-b. This method can be used for both the system a-R-a / b-R’-b and the system of a-R-b. Case 2 Adding monofunctional monomer R"-b to capture the end group
① The systems of a-R-a + b-R ‘ -b with the same mole ratio The number of the R"-b is N C The coefficient 2 of Nc is required since quantitatively one molecule R”-b has the same effect as one excess molecule b-R’-b on restricting the polymer chain growing.
② The system of a-R-b The number of the R"-b is N C
The high purity of monomer Precise measurement Proper temperature control Protected by inert gas, along with using catalytic agent and vacuumizing the system Summary
The molecular weight distribution (also called Polydispersity Index) is then given by: Polydispersity Index As P→1 , D approaches to two. The value of D increases with increase of he extent of reaction. The broader the molecular weight distribution is, the more uniform the molecular weight is.