A Monte Carlo study on a 3-dimensional comb polymer translocation through a nanopore driven by an electric field

A lattice Monte Carlo simulation study of the translocation of comb polymers through a nanopore subjected to an electric field is presented. The translocation dynamics was extensively studied in terms of the applied electric field strength, the pore size, and the comb polymer topology. The variations of the most probable translocation time tau p and the mean translocation time (tau) as a function of the applied electric field strength show distinct features, the latter exhibiting a nonmonotonic dependence on the electric field. We were able to show the existence of a critical field strength delta & varepsilon;c defined by the narrowest distribution of the translocation time, which is closely related to the size of the nanopore. In addition, we have found that the critical field strength also defines a transition point between two regimes of translocation: a smooth translocation for a field strength below delta & varepsilon;(c) and a chaotic translocation for a field strength above delta & varepsilon;(c) . Moreover, for the smallest pore size (rp = 1), monomers can only cross the nanopore in a single file, while for larger pores different modes of polymer translocation are identified. Finally, the dependence of the mean translocation time on the backbone length is governed by a power law relationship (tau) similar to N-B(alpha), where the scaling exponent alpha is found to be in the range of 1.3-1.7 for the set of side chain lengths and nanopore sizes investigated. As for the side chain length N- (S), the mean translocation time is found to follow a linear dependence <tau > similar to N-S.