Preferred penetration of active nano-rods into narrow channels and their clustering

Zhengjia Wang, Kang Ching Chu, Heng Kwong Tsao, Yu Jane Sheng

Research output: Contribution to journalArticlepeer-review

1 Scopus citations

Abstract

In a channel connected to a reservoir, passive particles prefer staying in the reservoir than the channel due to the entropic effect, as the size of the particles is comparable to that of the channel. Self-propelled rods can exhibit out-of-equilibrium phenomena, and their partition behavior may differ from that of passive rods due to their persistent swimming ability. In this work, the distribution of active nano-rods between the nanoscale channel and reservoir is explored using dissipative particle dynamics. The ratio of the nano-rod concentration in the slit to that in the reservoir, defined as the partition ratioΨ, is a function of active force, channel width, and rod length. Although passive nano-rods prefer staying in bulk (Ψ< 1), active rods can overcome the entropic barrier and show favorable partition toward narrow channels (Ψ> 1). As the slit width decreases to about the rod's width, active rods entering the slit behave like a quasi-two-dimensional system dynamically. At sufficiently high concentrations and Peclet numbers, nano-rods tend to align and move together in the same direction for a certain time. The distribution (PM) of the cluster size (M) follows a power law,PM∝M−2, for small clusters.

Original languageEnglish
Pages (from-to)16234-16241
Number of pages8
JournalPhysical Chemistry Chemical Physics
Volume23
Issue number30
DOIs
StatePublished - 14 Aug 2021

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