Carother's equation

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In step-growth polymerization, Carother's equation gives the number-average degree of polymerization, X_n, for a given fractional monomer conversion, p.

$\bar{X}_n=\frac{1}{1-p}$

Notes:

X_n is also the average chain length (in monomer units)
p = (N₀-N)/N₀, where:

N₀ is the number of molecules present initially

N is the number of unreacted molecules at time t

p is also a measure of the extent of reaction, or yield

A high monomer conversion is required to achieve a high number-average degree of polymerization. For example, a monomer conversion, p, of 98% is required for X_n = 50, and p = 99% is required for X_n = 100.

[edit] Related equations

Related to the Carother's equation are the following equations:

$\begin{matrix} \bar{X}_w & = & \frac{1+p}{1-p} \\ \bar{M}_n & = & M_o\frac{1}{1-p} \\ \bar{M}_w & = & M_o\frac{1+p}{1-p}\\ PDI & = & \frac{\bar{M}_w}{\bar{M}_n}=1+p\\ \end{matrix}$

where:

X_w is the weight average degree of polymerization,
M_n is the number average molecular weight,
M_w is the weight average molecular weight,
M_o is the molecular weight of the repeating monomer unit,
PDI is the polydispersity index

The last equation shows that the minimum value of the PDI is 2, which occurs at a monomer conversion of 100%.

In practise the average length of the polymer chain is limited by such things as the purity of the reactants, the absence of any side reactions (i.e. high yield), and the viscosity of the medium.

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Category: Polymer chemistry

Carother's equation

From Wikipedia, the free encyclopedia

[edit] Related equations

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