Influence of trap location on the efficiency of trapping in dendrimers and regular hyperbranched polymers

TL;DR

This study investigates how trap location affects trapping efficiency in dendrimers and hyperbranched polymers modeled by Cayley trees and Vicsek fractals, revealing topology-dependent differences in trapping dynamics.

Contribution

The paper provides exact formulas and numerical solutions for average trapping times in two polymer models, highlighting the impact of trap position and topology on trapping efficiency.

Findings

Trap location significantly affects trapping efficiency in Cayley trees.

In Vicsek fractals, trap position has negligible effect on trapping efficiency.

Trapping is generally more efficient in Cayley trees than in Vicsek fractals.

Abstract

In this paper, we study the trapping problem in two representative polymer networks, Cayley trees and Vicsek fractals, which separately model dendrimers and regular hyperbranched polymers. Our goal is to explore the impact of trap location on the efficiency of trapping in these two important polymer systems, with the efficiency being measured by the average trapping time (ATT) that is the average of source-to-trap mean first-passage time over every staring point in the whole networks. For Cayley trees, we derive an exact analytic formula for the ATT to an arbitrary trap node, based on which we further obtain the explicit expression of ATT for the case that the trap is uniformly distributed. For Vicsek fractals, we provide the closed-form solution for ATT to a peripheral node farthest from the central node, as well as the numerical solutions for the case when the trap is placed on other nodes. Moreover, we derive the exact formula for the ATT corresponding to the trapping problem when the trap has an uniform distribution over all nodes. Our results show that the influence of trap location on the trapping efficiency is completely different for the two polymer networks. In Cayley trees, the leading scaling of ATT increases with the shortest distance between the trap and the central node, implying that trap's position has an essential impact on the trapping efficiency; while in Vicsek fractals, the effect of location of the trap is negligible, since the dominant behavior of ATT is identical, respective of the location where the trap is placed. We also present that for all cases of trapping problems being studied, the trapping process is more efficient in Cayley trees than in Vicsek fractals. We demonstrate that all differences related to trapping in the two polymer systems are rooted in their underlying topological structures.