Diffusion of Thin Nanorods in Polymer Melts

Jiuling Wang; Thomas C. O'Connor; Gary S. Grest; Yitong Zheng; Michael Rubinstein; Ting Ge

doi:10.1021/acs.macromol.1c00989

Diffusion of Thin Nanorods in Polymer Melts

Jiuling Wang, Thomas C. O'Connor, Gary S. Grest, Yitong Zheng, Michael Rubinstein, Ting Ge^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

24 Citations (Scopus)

Abstract

The diffusion of monomerically thin nanorods in polymer melts is studied by molecular dynamics simulations. We focus on the systems where the chains are long enough to screen the hydrodynamic interactions, in which case the diffusion coefficient D∥ for the direction parallel to the rod decreases linearly with increasing rod length l. In unentangled polymers, the diffusion coefficient for the direction normal to the rod exhibits a crossover from D⊥ ∼l-2 to ∼l-1 with increasing l, corresponding to a progressive coupling of nanorod motion to the polymers. Accordingly, the rotational diffusion coefficient DR ≈ D⊥l-2 ∼l-4 and then DR ∼l-3 as l increases. In entangled polymers, D⊥ and DR are suppressed for l larger than the entanglement mesh size a. D⊥ ∼l-3 and DR ∼l-5 for l sufficiently above a, in agreement with de Gennes' rod reptation model.

Original language	English
Pages (from-to)	7051-7059
Number of pages	9
Journal	Macromolecules
Volume	54
Issue number	15
DOIs	https://doi.org/10.1021/acs.macromol.1c00989
Publication status	Published - 10 Aug 2021
Externally published	Yes

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title = "Diffusion of Thin Nanorods in Polymer Melts",

abstract = "The diffusion of monomerically thin nanorods in polymer melts is studied by molecular dynamics simulations. We focus on the systems where the chains are long enough to screen the hydrodynamic interactions, in which case the diffusion coefficient D∥ for the direction parallel to the rod decreases linearly with increasing rod length l. In unentangled polymers, the diffusion coefficient for the direction normal to the rod exhibits a crossover from D⊥ ∼l-2 to ∼l-1 with increasing l, corresponding to a progressive coupling of nanorod motion to the polymers. Accordingly, the rotational diffusion coefficient DR ≈ D⊥l-2 ∼l-4 and then DR ∼l-3 as l increases. In entangled polymers, D⊥ and DR are suppressed for l larger than the entanglement mesh size a. D⊥ ∼l-3 and DR ∼l-5 for l sufficiently above a, in agreement with de Gennes' rod reptation model.",

author = "Jiuling Wang and O'Connor, {Thomas C.} and Grest, {Gary S.} and Yitong Zheng and Michael Rubinstein and Ting Ge",

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T1 - Diffusion of Thin Nanorods in Polymer Melts

AU - Wang, Jiuling

AU - O'Connor, Thomas C.

AU - Grest, Gary S.

AU - Zheng, Yitong

AU - Rubinstein, Michael

AU - Ge, Ting

PY - 2021/8/10

Y1 - 2021/8/10

N2 - The diffusion of monomerically thin nanorods in polymer melts is studied by molecular dynamics simulations. We focus on the systems where the chains are long enough to screen the hydrodynamic interactions, in which case the diffusion coefficient D∥ for the direction parallel to the rod decreases linearly with increasing rod length l. In unentangled polymers, the diffusion coefficient for the direction normal to the rod exhibits a crossover from D⊥ ∼l-2 to ∼l-1 with increasing l, corresponding to a progressive coupling of nanorod motion to the polymers. Accordingly, the rotational diffusion coefficient DR ≈ D⊥l-2 ∼l-4 and then DR ∼l-3 as l increases. In entangled polymers, D⊥ and DR are suppressed for l larger than the entanglement mesh size a. D⊥ ∼l-3 and DR ∼l-5 for l sufficiently above a, in agreement with de Gennes' rod reptation model.

AB - The diffusion of monomerically thin nanorods in polymer melts is studied by molecular dynamics simulations. We focus on the systems where the chains are long enough to screen the hydrodynamic interactions, in which case the diffusion coefficient D∥ for the direction parallel to the rod decreases linearly with increasing rod length l. In unentangled polymers, the diffusion coefficient for the direction normal to the rod exhibits a crossover from D⊥ ∼l-2 to ∼l-1 with increasing l, corresponding to a progressive coupling of nanorod motion to the polymers. Accordingly, the rotational diffusion coefficient DR ≈ D⊥l-2 ∼l-4 and then DR ∼l-3 as l increases. In entangled polymers, D⊥ and DR are suppressed for l larger than the entanglement mesh size a. D⊥ ∼l-3 and DR ∼l-5 for l sufficiently above a, in agreement with de Gennes' rod reptation model.

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Diffusion of Thin Nanorods in Polymer Melts

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