Scale-free cluster-cluster aggregation during polymer collapse

Abstract

An extended polymer collapses to form a globule when subjected to a quench below the collapse transition temperature. The process begins with the formation of clusters of monomers or ``pearls''. The nascent clusters merge, resulting in growth of the average cluster size Cs, eventually leading to a single globule. The aggregation of the clusters are known to be analogous to droplet coalescence. This suggests a striking resemblance between such an aggregation and cluster-cluster aggregation found in many particle systems, like in colloidal self-assembly, typically characterized by a universal dynamic scaling behavior. Motivated by that, here, we verify the presence of such dynamic scaling during the collapse of a polymer with varying bending stiffness , using molecular dynamic simulations. We probe the dynamics via time evolution of the size distribution of clusters Ns(t) and growth of Cs(t). Irrespective of , we observe the power-law scalings Cs(t) tz and Ns(t) t-w s-τ, of which only the cluster growth is universal with z≈ 1.67. Importantly, our results indeed show that Ns(t) exhibits a dynamic scaling of the form Ns(t) s-2f(s/tz), indicative of a scale-free cluster growth. Interestingly, for flexible and weakly stiff polymers the dynamic exponents obey the relation w=2z, as also found in diffusion-controlled cluster-cluster aggregation of particles. For 5, the exponents show deviation from this relation, which grows continuously with . We identify the differences in local structures of the clusters formed, leading to variations in cluster-size dependence of the effective diffusion constant to be the origin of the above deviation. We also discuss potential experimental strategies to directly visualize the observed dynamic scaling in a collapsing polymer.