Branched Polymers with Excluded Volume Effects/ Relationship between Polymer Dimensions and Generation Number

Abstract: We discuss the extension of the empirical equation: $\left\langle s_{N}^{2}\right\rangle_{0}\propto g\,l^{2}$, where the subscript 0 denotes the ideal value with no excluded volume and $g$ the generation number from the root to the youngest (outermost) generation. By analogy with the linear chain problem, we introduce the assumption that the scaling relation, $\left\langle s_{N}^{2}\right\rangle_{0}\propto g^{2\lambda}\,l^{2}$, exists for arbitrary polymeric architectures, where $\lambda$ is an exponent for the backbone structure. Then, making use of the relationship between $g$ and $N$ (monomer number), we can deduce the exponent, $\nu$, for polymers with various architectures. The theory of the excluded volume effects impose the severe restriction on the quantities: $\nu_{0}$, $\nu$, and $\lambda$; for instance, the inequality, $\nu_{0}\ge\frac{1}{d+1}$, must be satisfied for isolated polymers in good solvents. An intriguing question is whether or not there exists an actual molecule that violates this inequality. We take up two examples having $\nu_{0}=1/4$ for $d=2$ and $\nu_{0}=1/6$ for $d=3$, and discuss this question.