Conversion Dependence of the Average Mean-Square Radii of

statistical parameter in conformational statistics of polymer chains. The quantity may be averaged over the polymer molecular weight distribution to g...
0 downloads 0 Views 30KB Size
3306

Macromolecules 2002, 35, 3306-3308

Notes Conversion Dependence of the Average Mean-Square Radii of Gyration for Hyperbranched Polymers Formed by ABg Type Monomers

with

Cn )

(2)

where x is the conversion of B groups and Cn is the combinatorial coefficient which stands for the number of isomeric structures formed by n ABg monomers. In obtaining the above equations, the assumption of ideal network polymerization was retained; i.e., all functional groups of the same type are equally reactive, all groups react independently, and no intramolecular reactions occur in finite species. The combinatorial coefficient Cn satisfies the decomposition formula

Xinwu Ba,* Haijun Wang, Min Zhao, and Mingxian Li Department of Chemistry, Hebei University, Baoding 071002, P. R. China Received July 16, 2001 Revised Manuscript Received January 8, 2002

Introduction Hyperbranched polymers are typically prepared by polymerization of ABg type monomers, where A and B are two different functional groups capable of reacting with each other and g is the number of B groups. When g is 2 or greater, polymerization of such monomers gives highly branched polymers, in which the formation of infinite large network structure was avoided.2 The mean-square radius of gyration is the important statistical parameter in conformational statistics of polymer chains. The quantity may be averaged over the polymer molecular weight distribution to give the average mean-square radius of gyration, which is experimentally accessible. For example, the z-average meansquare radius of gyration is generally determined from light scattering experiments,1 and therefore understanding this quantity varying with the conversion or reaction time may help to improve the present knowledge about the architecture of the elementary structure and formation kinetics. In the note, a decomposition formula of the combinatorial coefficient, which counts for the isomeric structures formed by the same number of ABg type monomers, is first determined. The statistical interpretation of this formula, which is similar to the argument proposed by Dobson and Gordon5,6 and some of the authors9 for the branched polymers, is proposed to give the mean-square radius of gyration without excludedvolume effect. Then the theoretical calculations for the average mean-square radii are carried out to give the explicit expressions of the weight- and z-average meansquare radii of gyration depending on the conversion of B groups, in which the contribution of the unreacted monomers in hyperbranched polymer systems is included and excluded, respectively. Number of Isomeric Structures and Mean-Square Radius of Gyration The molecular weight distribution Pn for ABg type hyperbranched polymer system can be expressed as2

Pn ) W0Cn(1 - gx)xn-1(1 - x)gn-n+1

(gn)! (gn - n + 1)!n!

(1)

Cn )

1

∑i CiCn-i(gn - n + 2)

2(n - 1)

(3)

To interpret eq 3 more clearly, let us rewrite it in a symmetric form

(n - 1)Cn )

∑E(n,i)

(4)

i